Network Working Group J. Quittek
Request for Comments: 5102 NEC
Category: Standards Track S. Bryant
B. Claise
P. Aitken
Cisco Systems, Inc.
J. Meyer
PayPal
January 2008
Information Model for IP Flow Information Export
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.
Abstract
This memo defines an information model for the IP Flow Information
eXport (IPFIX) protocol. It is used by the IPFIX protocol for
encoding measured traffic information and information related to the
traffic Observation Point, the traffic Metering Process, and the
Exporting Process. Although developed for the IPFIX protocol, the
model is defined in an open way that easily allows using it in other
protocols, interfaces, and applications.
Table of Contents
1. Introduction ....................................................6
2. Properties of IPFIX Protocol Information Elements ...............7
2.1. Information Elements Specification Template ................7
2.2. Scope of Information Elements ..............................9
2.3. Naming Conventions for Information Elements ................9
3. Type Space .....................................................10
3.1. Abstract Data Types .......................................10
3.1.1. unsigned8 ..........................................10
3.1.2. unsigned16 .........................................11
3.1.3. unsigned32 .........................................11
3.1.4. unsigned64 .........................................11
3.1.5. signed8 ............................................11
3.1.6. signed16 ...........................................11
3.1.7. signed32 ...........................................11
3.1.8. signed64 ...........................................11
Quittek, et al. Standards Track [Page 1]
RFC 5102 IPFIX Information Model January 2008
3.1.9. float32 ............................................11
3.1.10. float64 ...........................................11
3.1.11. boolean ...........................................12
3.1.12. macAddress ........................................12
3.1.13. octetArray ........................................12
3.1.14. string ............................................12
3.1.15. dateTimeSeconds ...................................12
3.1.16. dateTimeMilliseconds ..............................12
3.1.17. dateTimeMicroseconds ..............................12
3.1.18. dateTimeNanoseconds ...............................13
3.1.19. ipv4Address .......................................13
3.1.20. ipv6Address .......................................13
3.2. Data Type Semantics .......................................13
3.2.1. quantity ...........................................13
3.2.2. totalCounter .......................................13
3.2.3. deltaCounter .......................................14
3.2.4. identifier .........................................14
3.2.5. flags ..............................................14
4. Information Element Identifiers ................................14
5. Information Elements ...........................................18
5.1. Identifiers ...............................................19
5.1.1. lineCardId .........................................20
5.1.2. portId .............................................20
5.1.3. ingressInterface ...................................20
5.1.4. egressInterface ....................................21
5.1.5. meteringProcessId ..................................21
5.1.6. exportingProcessId .................................21
5.1.7. flowId .............................................22
5.1.8. templateId .........................................22
5.1.9. observationDomainId ................................22
5.1.10. observationPointId ................................23
5.1.11. commonPropertiesId ................................23
5.2. Metering and Exporting Process Configuration ..............23
5.2.1. exporterIPv4Address ................................24
5.2.2. exporterIPv6Address ................................24
5.2.3. exporterTransportPort ..............................24
5.2.4. collectorIPv4Address ...............................25
5.2.5. collectorIPv6Address ...............................25
5.2.6. exportInterface ....................................25
5.2.7. exportProtocolVersion ..............................26
5.2.8. exportTransportProtocol ............................26
5.2.9. collectorTransportPort .............................27
5.2.10. flowKeyIndicator ..................................27
5.3. Metering and Exporting Process Statistics .................28
5.3.1. exportedMessageTotalCount ..........................28
5.3.2. exportedOctetTotalCount ............................28
5.3.3. exportedFlowRecordTotalCount .......................29
5.3.4. observedFlowTotalCount .............................29
Quittek, et al. Standards Track [Page 2]
RFC 5102 IPFIX Information Model January 2008
5.3.5. ignoredPacketTotalCount ............................29
5.3.6. ignoredOctetTotalCount .............................30
5.3.7. notSentFlowTotalCount ..............................30
5.3.8. notSentPacketTotalCount ............................30
5.3.9. notSentOctetTotalCount .............................31
5.4. IP Header Fields ..........................................31
5.4.1. ipVersion ..........................................31
5.4.2. sourceIPv4Address ..................................32
5.4.3. sourceIPv6Address ..................................32
5.4.4. sourceIPv4PrefixLength .............................32
5.4.5. sourceIPv6PrefixLength .............................33
5.4.6. sourceIPv4Prefix ...................................33
5.4.7. sourceIPv6Prefix ...................................33
5.4.8. destinationIPv4Address .............................33
5.4.9. destinationIPv6Address .............................34
5.4.10. destinationIPv4PrefixLength .......................34
5.4.11. destinationIPv6PrefixLength .......................34
5.4.12. destinationIPv4Prefix .............................34
5.4.13. destinationIPv6Prefix .............................35
5.4.14. ipTTL .............................................35
5.4.15. protocolIdentifier ................................35
5.4.16. nextHeaderIPv6 ....................................36
5.4.17. ipDiffServCodePoint ...............................36
5.4.18. ipPrecedence ......................................36
5.4.19. ipClassOfService ..................................37
5.4.20. postIpClassOfService ..............................37
5.4.21. flowLabelIPv6 .....................................38
5.4.22. isMulticast .......................................38
5.4.23. fragmentIdentification ............................39
5.4.24. fragmentOffset ....................................39
5.4.25. fragmentFlags .....................................39
5.4.26. ipHeaderLength ....................................40
5.4.27. ipv4IHL ...........................................40
5.4.28. totalLengthIPv4 ...................................41
5.4.29. ipTotalLength .....................................41
5.4.30. payloadLengthIPv6 .................................41
5.5. Transport Header Fields ...................................42
5.5.1. sourceTransportPort ................................42
5.5.2. destinationTransportPort ...........................42
5.5.3. udpSourcePort ......................................43
5.5.4. udpDestinationPort .................................43
5.5.5. udpMessageLength ...................................43
5.5.6. tcpSourcePort ......................................44
5.5.7. tcpDestinationPort .................................44
5.5.8. tcpSequenceNumber ..................................44
5.5.9. tcpAcknowledgementNumber ...........................44
5.5.10. tcpWindowSize .....................................45
5.5.11. tcpWindowScale ....................................45
Quittek, et al. Standards Track [Page 3]
RFC 5102 IPFIX Information Model January 2008
5.5.12. tcpUrgentPointer ..................................45
5.5.13. tcpHeaderLength ...................................45
5.5.14. icmpTypeCodeIPv4 ..................................46
5.5.15. icmpTypeIPv4 ......................................46
5.5.16. icmpCodeIPv4 ......................................46
5.5.17. icmpTypeCodeIPv6 ..................................46
5.5.18. icmpTypeIPv6 ......................................47
5.5.19. icmpCodeIPv6 ......................................47
5.5.20. igmpType ..........................................47
5.6. Sub-IP Header Fields ......................................48
5.6.1. sourceMacAddress ...................................48
5.6.2. postSourceMacAddress ...............................48
5.6.3. vlanId .............................................49
5.6.4. postVlanId .........................................49
5.6.5. destinationMacAddress ..............................49
5.6.6. postDestinationMacAddress ..........................49
5.6.7. wlanChannelId ......................................50
5.6.8. wlanSSID ...........................................50
5.6.9. mplsTopLabelTTL ....................................50
5.6.10. mplsTopLabelExp ...................................51
5.6.11. postMplsTopLabelExp ...............................51
5.6.12. mplsLabelStackDepth ...............................51
5.6.13. mplsLabelStackLength ..............................52
5.6.14. mplsPayloadLength .................................52
5.6.15. mplsTopLabelStackSection ..........................52
5.6.16. mplsLabelStackSection2 ............................53
5.6.17. mplsLabelStackSection3 ............................53
5.6.18. mplsLabelStackSection4 ............................53
5.6.19. mplsLabelStackSection5 ............................54
5.6.20. mplsLabelStackSection6 ............................54
5.6.21. mplsLabelStackSection7 ............................54
5.6.22. mplsLabelStackSection8 ............................55
5.6.23. mplsLabelStackSection9 ............................55
5.6.24. mplsLabelStackSection10 ...........................55
5.7. Derived Packet Properties .................................56
5.7.1. ipPayloadLength ....................................56
5.7.2. ipNextHopIPv4Address ...............................56
5.7.3. ipNextHopIPv6Address ...............................57
5.7.4. bgpSourceAsNumber ..................................57
5.7.5. bgpDestinationAsNumber .............................57
5.7.6. bgpNextAdjacentAsNumber ............................57
5.7.7. bgpPrevAdjacentAsNumber ............................58
5.7.8. bgpNextHopIPv4Address ..............................58
5.7.9. bgpNextHopIPv6Address ..............................58
5.7.10. mplsTopLabelType ..................................59
5.7.11. mplsTopLabelIPv4Address ...........................59
5.7.12. mplsTopLabelIPv6Address ...........................60
5.7.13. mplsVpnRouteDistinguisher .........................60
Quittek, et al. Standards Track [Page 4]
RFC 5102 IPFIX Information Model January 2008
5.8. Min/Max Flow Properties ...................................61
5.8.1. minimumIpTotalLength ...............................61
5.8.2. maximumIpTotalLength ...............................61
5.8.3. minimumTTL .........................................61
5.8.4. maximumTTL .........................................62
5.8.5. ipv4Options ........................................62
5.8.6. ipv6ExtensionHeaders ...............................64
5.8.7. tcpControlBits .....................................65
5.8.8. tcpOptions .........................................66
5.9. Flow Timestamps ...........................................67
5.9.1. flowStartSeconds ...................................67
5.9.2. flowEndSeconds .....................................68
5.9.3. flowStartMilliseconds ..............................68
5.9.4. flowEndMilliseconds ................................68
5.9.5. flowStartMicroseconds ..............................68
5.9.6. flowEndMicroseconds ................................68
5.9.7. flowStartNanoseconds ...............................69
5.9.8. flowEndNanoseconds .................................69
5.9.9. flowStartDeltaMicroseconds .........................69
5.9.10. flowEndDeltaMicroseconds ..........................69
5.9.11. systemInitTimeMilliseconds ........................70
5.9.12. flowStartSysUpTime ................................70
5.9.13. flowEndSysUpTime ..................................70
5.10. Per-Flow Counters ........................................70
5.10.1. octetDeltaCount ...................................71
5.10.2. postOctetDeltaCount ...............................71
5.10.3. octetDeltaSumOfSquares ............................72
5.10.4. octetTotalCount ...................................72
5.10.5. postOctetTotalCount ...............................72
5.10.6. octetTotalSumOfSquares ............................72
5.10.7. packetDeltaCount ..................................73
5.10.8. postPacketDeltaCount ..............................73
5.10.9. packetTotalCount ..................................73
5.10.10. postPacketTotalCount .............................74
5.10.11. droppedOctetDeltaCount ...........................74
5.10.12. droppedPacketDeltaCount ..........................74
5.10.13. droppedOctetTotalCount ...........................74
5.10.14. droppedPacketTotalCount ..........................75
5.10.15. postMCastPacketDeltaCount ........................75
5.10.16. postMCastOctetDeltaCount .........................75
5.10.17. postMCastPacketTotalCount ........................76
5.10.18. postMCastOctetTotalCount .........................76
5.10.19. tcpSynTotalCount .................................76
5.10.20. tcpFinTotalCount .................................77
5.10.21. tcpRstTotalCount .................................77
5.10.22. tcpPshTotalCount .................................77
5.10.23. tcpAckTotalCount .................................78
5.10.24. tcpUrgTotalCount .................................78
Quittek, et al. Standards Track [Page 5]
RFC 5102 IPFIX Information Model January 2008
5.11. Miscellaneous Flow Properties ............................78
5.11.1. flowActiveTimeout .................................79
5.11.2. flowIdleTimeout ...................................79
5.11.3. flowEndReason .....................................79
5.11.4. flowDurationMilliseconds ..........................80
5.11.5. flowDurationMicroseconds ..........................80
5.11.6. flowDirection .....................................80
5.12. Padding ..................................................80
5.12.1. paddingOctets .....................................81
6. Extending the Information Model ................................81
7. IANA Considerations ............................................82
7.1. IPFIX Information Elements ................................82
7.2. MPLS Label Type Identifier ................................82
7.3. XML Namespace and Schema ..................................83
8. Security Considerations ........................................83
9. Acknowledgements ...............................................84
10. References ....................................................84
10.1. Normative References .....................................84
10.2. Informative References ...................................84
Appendix A. XML Specification of IPFIX Information Elements .......88
Appendix B. XML Specification of Abstract Data Types .............157
1. Introduction
The IP Flow Information eXport (IPFIX) protocol serves for
transmitting information related to measured IP traffic over the
Internet. The protocol specification in [RFC5101] defines how
Information Elements are transmitted. For Information Elements, it
specifies the encoding of a set of basic data types. However, the
list of Information Elements that can be transmitted by the protocol,
such as Flow attributes (source IP address, number of packets, etc.)
and information about the Metering and Exporting Process (packet
Observation Point, sampling rate, Flow timeout interval, etc.), is
not specified in [RFC5101].
This document complements the IPFIX protocol specification by
providing the IPFIX information model. IPFIX-specific terminology
used in this document is defined in Section 2 of [RFC5101]. As in
[RFC5101], these IPFIX-specific terms have the first letter of a word
capitalized when used in this document.
The use of the term 'information model' is not fully in line with the
definition of this term in [RFC3444]. The IPFIX information model
does not specify relationships between Information Elements, but also
it does not specify a concrete encoding of Information Elements.
Besides the encoding used by the IPFIX protocol, other encodings of
IPFIX Information Elements can be applied, for example, XML-based
encodings.
Quittek, et al. Standards Track [Page 6]
RFC 5102 IPFIX Information Model January 2008
The main part of this document is Section 5, which defines the
(extensible) list of Information Elements to be transmitted by the
IPFIX protocol. Section 2 defines a template for specifying IPFIX
Information Elements in Section 5. Section 3 defines the set of
abstract data types that are available for IPFIX Information
Elements. Section 6 discusses extensibility of the IPFIX information
model.
The main bodies of Sections 2, 3, and 5 were generated from XML
documents. The XML-based specification of template, abstract data
types, and IPFIX Information Elements can be used for automatically
checking syntactical correctness of the specification of IPFIX
Information Elements. It can further be used for generating IPFIX
protocol implementation code that deals with processing IPFIX
Information Elements. Also, code for applications that further
process traffic information transmitted via the IPFIX protocol can be
generated with the XML specification of IPFIX Information Elements.
For that reason, the XML document that served as a source for Section
5 and the XML schema that served as source for Sections 2 and 3 are
attached to this document in Appendices A and B.
Note that although partially generated from the attached XML
documents, the main body of this document is normative while the
appendices are informational.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in [RFC2119].
2. Properties of IPFIX Protocol Information Elements
2.1. Information Elements Specification Template
Information in messages of the IPFIX protocol is modeled in terms of
Information Elements of the IPFIX information model. IPFIX
Information Elements are specified in Section 5. For specifying
these Information Elements, a template is used that is described
below.
All Information Elements specified for the IPFIX protocol either in
this document or by any future extension MUST have the following
properties defined:
name - A unique and meaningful name for the Information Element.
Quittek, et al. Standards Track [Page 7]
RFC 5102 IPFIX Information Model January 2008
elementId - A numeric identifier of the Information Element. If this
identifier is used without an enterprise identifier (see [RFC5101]
and enterpriseId below), then it is globally unique and the list
of allowed values is administered by IANA. It is used for compact
identification of an Information Element when encoding Templates
in the protocol.
description - The semantics of this Information Element. Describes
how this Information Element is derived from the Flow or other
information available to the observer.
dataType - One of the types listed in Section 3.1 of this document or
in a future extension of the information model. The type space
for attributes is constrained to facilitate implementation. The
existing type space does however encompass most basic types used
in modern programming languages, as well as some derived types
(such as ipv4Address) that are common to this domain and useful to
distinguish.
status - The status of the specification of this Information Element.
Allowed values are 'current', 'deprecated', and 'obsolete'.
Enterprise-specific Information Elements MUST have the following
property defined:
enterpriseId - Enterprises may wish to define Information Elements
without registering them with IANA, for example, for
enterprise-internal purposes. For such Information Elements, the
Information Element identifier described above is not sufficient
when the Information Element is used outside the enterprise. If
specifications of enterprise-specific Information Elements are
made public and/or if enterprise-specific identifiers are used by
the IPFIX protocol outside the enterprise, then the
enterprise-specific identifier MUST be made globally unique by
combining it with an enterprise identifier. Valid values for the
enterpriseId are defined by IANA as Structure of Management
Information (SMI) network management private enterprise codes.
They are defined at http://www.iana.org/assignments/enterprise-
numbers.
All Information Elements specified for the IPFIX protocol either in
this document or by any future extension MAY have the following
properties defined:
dataTypeSemantics - The integral types may be qualified by additional
semantic details. Valid values for the data type semantics are
specified in Section 3.2 of this document or in a future extension
of the information model.
Quittek, et al. Standards Track [Page 8]
RFC 5102 IPFIX Information Model January 2008
units - If the Information Element is a measure of some kind, the
units identify what the measure is.
range - Some Information Elements may only be able to take on a
restricted set of values that can be expressed as a range (e.g., 0
through 511 inclusive). If this is the case, the valid inclusive
range should be specified.
reference - Identifies additional specifications that more precisely
define this item or provide additional context for its use.
2.2. Scope of Information Elements
By default, most Information Elements have a scope specified in their
definitions.
o The Information Elements defined in Sections 5.2 and 5.3 have a
default of "a specific Metering Process" or of "a specific
Exporting Process", respectively.
o The Information Elements defined in Sections 5.4-5.11 have a scope
of "a specific Flow".
Within Data Records defined by Option Templates, the IPFIX protocol
allows further limiting of the Information Element scope. The new
scope is specified by one or more scope fields and defined as the
combination of all specified scope values; see Section 3.4.2.1 on
IPFIX scopes in [RFC5101].
2.3. Naming Conventions for Information Elements
The following naming conventions were used for naming Information
Elements in this document. It is recommended that extensions of the
model use the same conventions.
o Names of Information Elements should be descriptive.
o Names of Information Elements that are not enterprise-specific
MUST be unique within the IPFIX information model.
Enterprise-specific Information Elements SHOULD be prefixed with a
vendor name.
o Names of Information Elements start with non-capitalized letters.
Quittek, et al. Standards Track [Page 9]
RFC 5102 IPFIX Information Model January 2008
o Composed names use capital letters for the first letter of each
component (except for the first one). All other letters are
non-capitalized, even for acronyms. Exceptions are made for
acronyms containing non-capitalized letter, such as 'IPv4' and
'IPv6'. Examples are sourceMacAddress and destinationIPv4Address.
o Middleboxes [RFC3234] may change Flow properties, such as the
Differentiated Service Code Point (DSCP) value or the source IP
address. If an IPFIX Observation Point is located in the path of
a Flow before one or more middleboxes that potentially modify
packets of the Flow, then it may be desirable to also report Flow
properties after the modification performed by the middleboxes.
An example is an Observation Point before a packet marker changing
a packet's IPv4 Type of Service (TOS) field that is encoded in
Information Element classOfServiceIPv4. Then the value observed
and reported by Information Element classOfServiceIPv4 is valid at
the Observation Point, but not after the packet passed the packet
marker. For reporting the change value of the TOS field, the
IPFIX information model uses Information Elements that have a name
prefix "post", for example, "postClassOfServiceIPv4". Information
Elements with prefix "post" report on Flow properties that are not
necessarily observed at the Observation Point, but which are
obtained within the Flow's Observation Domain by other means
considered to be sufficiently reliable, for example, by analyzing
the packet marker's marking tables.
3. Type Space
This section describes the abstract data types that can be used for
the specification of IPFIX Information Elements in Section 4.
Section 3.1 describes the set of abstract data types.
Abstract data types unsigned8, unsigned16, unsigned32, unsigned64,
signed8, signed16, signed32, and signed64 are integral data types.
As described in Section 3.2, their data type semantics can be further
specified, for example, by 'totalCounter', 'deltaCounter',
'identifier', or 'flags'.
3.1. Abstract Data Types
This section describes the set of valid abstract data types of the
IPFIX information model. Note that further abstract data types may
be specified by future extensions of the IPFIX information model.
3.1.1. unsigned8
The type "unsigned8" represents a non-negative integer value in the
range of 0 to 255.
Quittek, et al. Standards Track [Page 10]
RFC 5102 IPFIX Information Model January 2008
3.1.2. unsigned16
The type "unsigned16" represents a non-negative integer value in the
range of 0 to 65535.
3.1.3. unsigned32
The type "unsigned32" represents a non-negative integer value in the
range of 0 to 4294967295.
3.1.4. unsigned64
The type "unsigned64" represents a non-negative integer value in the
range of 0 to 18446744073709551615.
3.1.5. signed8
The type "signed8" represents an integer value in the range of -128
to 127.
3.1.6. signed16
The type "signed16" represents an integer value in the range of
-32768 to 32767.
3.1.7. signed32
The type "signed32" represents an integer value in the range of
-2147483648 to 2147483647.
3.1.8. signed64
The type "signed64" represents an integer value in the range of
-9223372036854775808 to 9223372036854775807.
3.1.9. float32
The type "float32" corresponds to an IEEE single-precision 32-bit
floating point type as defined in [IEEE.754.1985].
3.1.10. float64
The type "float64" corresponds to an IEEE double-precision 64-bit
floating point type as defined in [IEEE.754.1985].
Quittek, et al. Standards Track [Page 11]
RFC 5102 IPFIX Information Model January 2008
3.1.11. boolean
The type "boolean" represents a binary value. The only allowed
values are "true" and "false".
3.1.12. macAddress
The type "macAddress" represents a string of 6 octets.
3.1.13. octetArray
The type "octetArray" represents a finite-length string of octets.
3.1.14. string
The type "string" represents a finite-length string of valid
characters from the Unicode character encoding set [ISO.10646-
1.1993]. Unicode allows for ASCII [ISO.646.1991] and many other
international character sets to be used.
3.1.15. dateTimeSeconds
The type "dateTimeSeconds" represents a time value in units of
seconds based on coordinated universal time (UTC). The choice of an
epoch, for example, 00:00 UTC, January 1, 1970, is left to
corresponding encoding specifications for this type, for example, the
IPFIX protocol specification. Leap seconds are excluded. Note that
transformation of values might be required between different
encodings if different epoch values are used.
3.1.16. dateTimeMilliseconds
The type "dateTimeMilliseconds" represents a time value in units of
milliseconds based on coordinated universal time (UTC). The choice
of an epoch, for example, 00:00 UTC, January 1, 1970, is left to
corresponding encoding specifications for this type, for example, the
IPFIX protocol specification. Leap seconds are excluded. Note that
transformation of values might be required between different
encodings if different epoch values are used.
3.1.17. dateTimeMicroseconds
The type "dateTimeMicroseconds" represents a time value in units of
microseconds based on coordinated universal time (UTC). The choice
of an epoch, for example, 00:00 UTC, January 1, 1970, is left to
Quittek, et al. Standards Track [Page 12]
RFC 5102 IPFIX Information Model January 2008
corresponding encoding specifications for this type, for example, the
IPFIX protocol specification. Leap seconds are excluded. Note that
transformation of values might be required between different
encodings if different epoch values are used.
3.1.18. dateTimeNanoseconds
The type "dateTimeNanoseconds" represents a time value in units of
nanoseconds based on coordinated universal time (UTC). The choice of
an epoch, for example, 00:00 UTC, January 1, 1970, is left to
corresponding encoding specifications for this type, for example, the
IPFIX protocol specification. Leap seconds are excluded. Note that
transformation of values might be required between different
encodings if different epoch values are used.
3.1.19. ipv4Address
The type "ipv4Address" represents a value of an IPv4 address.
3.1.20. ipv6Address
The type "ipv6Address" represents a value of an IPv6 address.
3.2. Data Type Semantics
This section describes the set of valid data type semantics of the
IPFIX information model. Note that further data type semantics may
be specified by future extensions of the IPFIX information model.
3.2.1. quantity
A quantity value represents a discrete measured value pertaining to
the record. This is distinguished from counters that represent an
ongoing measured value whose "odometer" reading is captured as part
of a given record. If no semantic qualifier is given, the
Information Elements that have an integral data type should behave as
a quantity.
3.2.2. totalCounter
An integral value reporting the value of a counter. Counters are
unsigned and wrap back to zero after reaching the limit of the type.
For example, an unsigned64 with counter semantics will continue to
increment until reaching the value of 2**64 - 1. At this point, the
next increment will wrap its value to zero and continue counting from
zero. The semantics of a total counter is similar to the semantics
of counters used in SNMP, such as Counter32 defined in RFC 2578
[RFC2578]. The only difference between total counters and counters
Quittek, et al. Standards Track [Page 13]
RFC 5102 IPFIX Information Model January 2008
used in SNMP is that the total counters have an initial value of 0.
A total counter counts independently of the export of its value.
3.2.3. deltaCounter
An integral value reporting the value of a counter. Counters are
unsigned and wrap back to zero after reaching the limit of the type.
For example, an unsigned64 with counter semantics will continue to
increment until reaching the value of 2**64 - 1. At this point, the
next increment will wrap its value to zero and continue counting from
zero. The semantics of a delta counter is similar to the semantics
of counters used in SNMP, such as Counter32 defined in RFC 2578
[RFC2578]. The only difference between delta counters and counters
used in SNMP is that the delta counters have an initial value of 0.
A delta counter is reset to 0 each time its value is exported.
3.2.4. identifier
An integral value that serves as an identifier. Specifically,
mathematical operations on two identifiers (aside from the equality
operation) are meaningless. For example, Autonomous System ID 1 *
Autonomous System ID 2 is meaningless.
3.2.5. flags
An integral value that actually represents a set of bit fields.
Logical operations are appropriate on such values, but not other
mathematical operations. Flags should always be of an unsigned type.
4. Information Element Identifiers
All Information Elements defined in Section 5 of this document or in
future extensions of the IPFIX information model have their
identifiers assigned by IANA. Their identifiers can be retrieved at
http://www.iana.org/assignments/ipfix.
The value of these identifiers is in the range of 1-32767. Within
this range, Information Element identifier values in the sub-range of
1-127 are compatible with field types used by NetFlow version 9
[RFC3954].
Quittek, et al. Standards Track [Page 14]
RFC 5102 IPFIX Information Model January 2008
+---------------------------------+---------------------------------+
| Range of IANA-assigned | Description |
| Information Element identifiers | |
+---------------------------------+---------------------------------+
| 0 | Reserved. |
| 1-127 | Information Element identifiers |
| | compatible with NetFlow version |
| | 9 field types [RFC3954]. |
| 128-32767 | Further Information Element |
| | identifiers. |
+---------------------------------+---------------------------------+
Enterprise-specific Information Element identifiers have the same
range of 1-32767, but they are coupled with an additional enterprise
identifier. For enterprise-specific Information Elements,
Information Element identifier 0 is also reserved.
Enterprise-specific Information Element identifiers can be chosen by
an enterprise arbitrarily within the range of 1-32767. The same
identifier may be assigned by other enterprises for different
purposes.
Still, Collecting Processes can distinguish these Information
Elements because the Information Element identifier is coupled with
an enterprise identifier.
Enterprise identifiers MUST be registered as SMI network management
private enterprise code numbers with IANA. The registry can be found
at http://www.iana.org/assignments/enterprise-numbers.
The following list gives an overview of the Information Element
identifiers that are specified in Section 5 and are compatible with
field types used by NetFlow version 9 [RFC3954].
Quittek, et al. Standards Track [Page 15]
RFC 5102 IPFIX Information Model January 2008
+----+----------------------------+-------+-------------------------+
| ID | Name | ID | Name |
+----+----------------------------+-------+-------------------------+
| 1 | octetDeltaCount | 43 | RESERVED |
| 2 | packetDeltaCount | 44 | sourceIPv4Prefix |
| 3 | RESERVED | 45 | destinationIPv4Prefix |
| 4 | protocolIdentifier | 46 | mplsTopLabelType |
| 5 | ipClassOfService | 47 | mplsTopLabelIPv4Address |
| 6 | tcpControlBits | 48-51 | RESERVED |
| 7 | sourceTransportPort | 52 | minimumTTL |
| 8 | sourceIPv4Address | 53 | maximumTTL |
| 9 | sourceIPv4PrefixLength | 54 | fragmentIdentification |
| 10 | ingressInterface | 55 | postIpClassOfService |
| 11 | destinationTransportPort | 56 | sourceMacAddress |
| 12 | destinationIPv4Address | 57 |postDestinationMacAddress|
| 13 | destinationIPv4PrefixLength| 58 | vlanId |
| 14 | egressInterface | 59 | postVlanId |
| 15 | ipNextHopIPv4Address | 60 | ipVersion |
| 16 | bgpSourceAsNumber | 61 | flowDirection |
| 17 | bgpDestinationAsNumber | 62 | ipNextHopIPv6Address |
| 18 | bgpNexthopIPv4Address | 63 | bgpNexthopIPv6Address |
| 19 | postMCastPacketDeltaCount | 64 | ipv6ExtensionHeaders |
| 20 | postMCastOctetDeltaCount | 65-69 | RESERVED |
| 21 | flowEndSysUpTime | 70 | mplsTopLabelStackSection|
| 22 | flowStartSysUpTime | 71 | mplsLabelStackSection2 |
| 23 | postOctetDeltaCount | 72 | mplsLabelStackSection3 |
| 24 | postPacketDeltaCount | 73 | mplsLabelStackSection4 |
| 25 | minimumIpTotalLength | 74 | mplsLabelStackSection5 |
| 26 | maximumIpTotalLength | 75 | mplsLabelStackSection6 |
| 27 | sourceIPv6Address | 76 | mplsLabelStackSection7 |
| 28 | destinationIPv6Address | 77 | mplsLabelStackSection8 |
| 29 | sourceIPv6PrefixLength | 78 | mplsLabelStackSection9 |
| 30 | destinationIPv6PrefixLength| 79 | mplsLabelStackSection10 |
| 31 | flowLabelIPv6 | 80 | destinationMacAddress |
| 32 | icmpTypeCodeIPv4 | 81 | postSourceMacAddress |
| 33 | igmpType | 82-84 | RESERVED |
| 34 | RESERVED | 85 | octetTotalCount |
| 35 | RESERVED | 86 | packetTotalCount |
| 36 | flowActiveTimeout | 87 | RESERVED |
| 37 | flowIdleTimeout | 88 | fragmentOffset |
| 38 | RESERVED | 89 | RESERVED |
| 39 | RESERVED | 90 |mplsVpnRouteDistinguisher|
| 40 | exportedOctetTotalCount |91-127 | RESERVED |
| 41 | exportedMessageTotalCount | | |
| 42 |exportedFlowRecordTotalCount| | |
+----+----------------------------+-------+-------------------------+
Quittek, et al. Standards Track [Page 16]
RFC 5102 IPFIX Information Model January 2008
The following list gives an overview of the Information Element
identifiers that are specified in Section 5 and extends the list of
Information Element identifiers specified already in [RFC3954].
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 128 | bgpNextAdjacentAsNumber | 169 | destinationIPv6Prefix |
| 129 | bgpPrevAdjacentAsNumber | 170 | sourceIPv6Prefix |
| 130 | exporterIPv4Address | 171 | postOctetTotalCount |
| 131 | exporterIPv6Address | 172 | postPacketTotalCount |
| 132 | droppedOctetDeltaCount | 173 | flowKeyIndicator |
| 133 | droppedPacketDeltaCount | 174 | postMCastPacketTotalCount |
| 134 | droppedOctetTotalCount | 175 | postMCastOctetTotalCount |
| 135 | droppedPacketTotalCount | 176 | icmpTypeIPv4 |
| 136 | flowEndReason | 177 | icmpCodeIPv4 |
| 137 | commonPropertiesId | 178 | icmpTypeIPv6 |
| 138 | observationPointId | 179 | icmpCodeIPv6 |
| 139 | icmpTypeCodeIPv6 | 180 | udpSourcePort |
| 140 | mplsTopLabelIPv6Address | 181 | udpDestinationPort |
| 141 | lineCardId | 182 | tcpSourcePort |
| 142 | portId | 183 | tcpDestinationPort |
| 143 | meteringProcessId | 184 | tcpSequenceNumber |
| 144 | exportingProcessId | 185 | tcpAcknowledgementNumber |
| 145 | templateId | 186 | tcpWindowSize |
| 146 | wlanChannelId | 187 | tcpUrgentPointer |
| 147 | wlanSSID | 188 | tcpHeaderLength |
| 148 | flowId | 189 | ipHeaderLength |
| 149 | observationDomainId | 190 | totalLengthIPv4 |
| 150 | flowStartSeconds | 191 | payloadLengthIPv6 |
| 151 | flowEndSeconds | 192 | ipTTL |
| 152 | flowStartMilliseconds | 193 | nextHeaderIPv6 |
| 153 | flowEndMilliseconds | 194 | mplsPayloadLength |
| 154 | flowStartMicroseconds | 195 | ipDiffServCodePoint |
| 155 | flowEndMicroseconds | 196 | ipPrecedence |
| 156 | flowStartNanoseconds | 197 | fragmentFlags |
| 157 | flowEndNanoseconds | 198 | octetDeltaSumOfSquares |
| 158 | flowStartDeltaMicroseconds| 199 | octetTotalSumOfSquares |
| 159 | flowEndDeltaMicroseconds | 200 | mplsTopLabelTTL |
| 160 | systemInitTimeMilliseconds| 201 | mplsLabelStackLength |
| 161 | flowDurationMilliseconds | 202 | mplsLabelStackDepth |
| 162 | flowDurationMicroseconds | 203 | mplsTopLabelExp |
| 163 | observedFlowTotalCount | 204 | ipPayloadLength |
| 164 | ignoredPacketTotalCount | 205 | udpMessageLength |
| 165 | ignoredOctetTotalCount | 206 | isMulticast |
| 166 | notSentFlowTotalCount | 207 | ipv4IHL |
| 167 | notSentPacketTotalCount | 208 | ipv4Options |
| 168 | notSentOctetTotalCount | 209 | tcpOptions |
Quittek, et al. Standards Track [Page 17]
RFC 5102 IPFIX Information Model January 2008
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 210 | paddingOctets | 218 | tcpSynTotalCount |
| 211 | collectorIPv4Address | 219 | tcpFinTotalCount |
| 212 | collectorIPv6Address | 220 | tcpRstTotalCount |
| 213 | exportInterface | 221 | tcpPshTotalCount |
| 214 | exportProtocolVersion | 222 | tcpAckTotalCount |
| 215 | exportTransportProtocol | 223 | tcpUrgTotalCount |
| 216 | collectorTransportPort | 224 | ipTotalLength |
| 217 | exporterTransportPort | 237 | postMplsTopLabelExp |
| | | 238 | tcpWindowScale |
+-----+---------------------------+-----+---------------------------+
5. Information Elements
This section describes the Information Elements of the IPFIX
information model. The elements are grouped into 12 groups according
to their semantics and their applicability:
1. Identifiers
2. Metering and Exporting Process Configuration
3. Metering and Exporting Process Statistics
4. IP Header Fields
5. Transport Header Fields
6. Sub-IP Header Fields
7. Derived Packet Properties
8. Min/Max Flow Properties
9. Flow Timestamps
10. Per-Flow Counters
11. Miscellaneous Flow Properties
12. Padding
The Information Elements that are derived from fields of packets or
from packet treatment, such as the Information Elements in groups
4-7, can typically serve as Flow Keys used for mapping packets to
Flows.
If they do not serve as Flow Keys, their value may change from packet
to packet within a single Flow. For Information Elements with values
that are derived from fields of packets or from packet treatment and
for which the value may change from packet to packet within a single
Flow, the IPFIX information model defines that their value is
determined by the first packet observed for the corresponding Flow,
unless the description of the Information Element explicitly
specifies a different semantics. This simple rule allows writing all
Quittek, et al. Standards Track [Page 18]
RFC 5102 IPFIX Information Model January 2008
Information Elements related to header fields once when the first
packet of the Flow is observed. For further observed packets of the
same Flow, only Flow properties that depend on more than one packet,
such as the Information Elements in groups 8-11, need to be updated.
Information Elements with a name having the "post" prefix, for
example, "postClassOfServiceIPv4", do not report properties that were
actually observed at the Observation Point, but retrieved by other
means within the Observation Domain. These Information Elements can
be used if there are middlebox functions within the Observation
Domain changing Flow properties after packets passed the Observation
Point.
Information Elements in this section use the reference property to
reference [RFC0768], [RFC0791], [RFC0792], [RFC0793], [RFC1108],
[RFC1112], [RFC1191], [RFC1323], [RFC1385], [RFC1812], [RFC1930],
[RFC2113], [RFC2119], [RFC2460], [RFC2675], [RFC2863], [RFC3031],
[RFC3032], [RFC3193], [RFC3234], [RFC3260], [RFC3270], [RFC3376],
[RFC3954], [RFC4271], [RFC4291], [RFC4302], [RFC4303], [RFC4364],
[RFC4382], [RFC4443], [RFC4960], [RFC5036], [IEEE.802-11.1999],
[IEEE.802-1Q.2003], and [IEEE.802-3.2002].
5.1. Identifiers
Information Elements grouped in the table below are identifying
components of the IPFIX architecture, of an IPFIX Device, or of the
IPFIX protocol. All of them have an integral abstract data type and
data type semantics "identifier" as described in Section 3.2.4.
Typically, some of them are used for limiting scopes of other
Information Elements. However, other Information Elements MAY be
used for limiting scopes. Note also that all Information Elements
listed below MAY be used for other purposes than limiting scopes.
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 141 | lineCardId | 148 | flowId |
| 142 | portId | 145 | templateId |
| 10 | ingressInterface | 149 | observationDomainId |
| 14 | egressInterface | 138 | observationPointId |
| 143 | meteringProcessId | 137 | commonPropertiesId |
| 144 | exportingProcessId | | |
+-----+---------------------------+-----+---------------------------+
Quittek, et al. Standards Track [Page 19]
RFC 5102 IPFIX Information Model January 2008
5.1.1. lineCardId
Description:
An identifier of a line card that is unique per IPFIX Device
hosting an Observation Point. Typically, this Information Element
is used for limiting the scope of other Information Elements.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 141
Status: current
5.1.2. portId
Description:
An identifier of a line port that is unique per IPFIX Device
hosting an Observation Point. Typically, this Information Element
is used for limiting the scope of other Information Elements.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 142
Status: current
5.1.3. ingressInterface
Description:
The index of the IP interface where packets of this Flow are being
received. The value matches the value of managed object 'ifIndex'
as defined in RFC 2863. Note that ifIndex values are not assigned
statically to an interface and that the interfaces may be
renumbered every time the device's management system is
re-initialized, as specified in RFC 2863.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 10
Status: current
Reference:
See RFC 2863 for the definition of the ifIndex object.
Quittek, et al. Standards Track [Page 20]
RFC 5102 IPFIX Information Model January 2008
5.1.4. egressInterface
Description:
The index of the IP interface where packets of this Flow are being
sent. The value matches the value of managed object 'ifIndex' as
defined in RFC 2863. Note that ifIndex values are not assigned
statically to an interface and that the interfaces may be
renumbered every time the device's management system is
re-initialized, as specified in RFC 2863.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 14
Status: current
Reference:
See RFC 2863 for the definition of the ifIndex object.
5.1.5. meteringProcessId
Description:
An identifier of a Metering Process that is unique per IPFIX
Device. Typically, this Information Element is used for limiting
the scope of other Information Elements. Note that process
identifiers are typically assigned dynamically. The Metering
Process may be re-started with a different ID.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 143
Status: current
5.1.6. exportingProcessId
Description:
An identifier of an Exporting Process that is unique per IPFIX
Device. Typically, this Information Element is used for limiting
the scope of other Information Elements. Note that process
identifiers are typically assigned dynamically. The Exporting
Process may be re-started with a different ID.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 144
Status: current
Quittek, et al. Standards Track [Page 21]
RFC 5102 IPFIX Information Model January 2008
5.1.7. flowId
Description:
An identifier of a Flow that is unique within an Observation
Domain. This Information Element can be used to distinguish
between different Flows if Flow Keys such as IP addresses and port
numbers are not reported or are reported in separate records.
Abstract Data Type: unsigned64
Data Type Semantics: identifier
ElementId: 148
Status: current
5.1.8. templateId
Description:
An identifier of a Template that is locally unique within a
combination of a Transport session and an Observation Domain.
Template IDs 0-255 are reserved for Template Sets, Options
Template Sets, and other reserved Sets yet to be created.
Template IDs of Data Sets are numbered from 256 to 65535.
Typically, this Information Element is used for limiting the scope
of other Information Elements. Note that after a re-start of the
Exporting Process Template identifiers may be re-assigned.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 145
Status: current
5.1.9. observationDomainId
Description:
An identifier of an Observation Domain that is locally unique to
an Exporting Process. The Exporting Process uses the Observation
Domain ID to uniquely identify to the Collecting Process the
Observation Domain where Flows were metered. It is RECOMMENDED
that this identifier is also unique per IPFIX Device. A value of
0 indicates that no specific Observation Domain is identified by
this Information Element. Typically, this Information Element is
used for limiting the scope of other Information Elements.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 149
Status: current
Quittek, et al. Standards Track [Page 22]
RFC 5102 IPFIX Information Model January 2008
5.1.10. observationPointId
Description:
An identifier of an Observation Point that is unique per
Observation Domain. It is RECOMMENDED that this identifier is
also unique per IPFIX Device. Typically, this Information Element
is used for limiting the scope of other Information Elements.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 138
Status: current
5.1.11. commonPropertiesId
Description:
An identifier of a set of common properties that is unique per
Observation Domain and Transport Session. Typically, this
Information Element is used to link to information reported in
separate Data Records.
Abstract Data Type: unsigned64
Data Type Semantics: identifier
ElementId: 137
Status: current
5.2. Metering and Exporting Process Configuration
Information Elements in this section describe the configuration of
the Metering Process or the Exporting Process. The set of these
Information Elements is listed in the table below.
+-----+--------------------------+-----+----------------------------+
| ID | Name | ID | Name |
+-----+--------------------------+-----+----------------------------+
| 130 | exporterIPv4Address | 213 | exportInterface |
| 131 | exporterIPv6Address | 214 | exportProtocolVersion |
| 217 | exporterTransportPort | 215 | exportTransportProtocol |
| 211 | collectorIPv4Address | 216 | collectorTransportPort |
| 212 | collectorIPv6Address | 173 | flowKeyIndicator |
+-----+--------------------------+-----+----------------------------+
Quittek, et al. Standards Track [Page 23]
RFC 5102 IPFIX Information Model January 2008
5.2.1. exporterIPv4Address
Description:
The IPv4 address used by the Exporting Process. This is used by
the Collector to identify the Exporter in cases where the identity
of the Exporter may have been obscured by the use of a proxy.
Abstract Data Type: ipv4Address
Data Type Semantics: identifier
ElementId: 130
Status: current
5.2.2. exporterIPv6Address
Description:
The IPv6 address used by the Exporting Process. This is used by
the Collector to identify the Exporter in cases where the identity
of the Exporter may have been obscured by the use of a proxy.
Abstract Data Type: ipv6Address
Data Type Semantics: identifier
ElementId: 131
Status: current
5.2.3. exporterTransportPort
Description:
The source port identifier from which the Exporting Process sends
Flow information. For the transport protocols UDP, TCP, and SCTP,
this is the source port number. This field MAY also be used for
future transport protocols that have 16-bit source port
identifiers. This field may be useful for distinguishing multiple
Exporting Processes that use the same IP address.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 217
Status: current
Reference:
See RFC 768 for the definition of the UDP source port field. See
RFC 793 for the definition of the TCP source port field. See RFC
4960 for the definition of SCTP. Additional information on
defined UDP and TCP port numbers can be found at
http://www.iana.org/assignments/port-numbers.
Quittek, et al. Standards Track [Page 24]
RFC 5102 IPFIX Information Model January 2008
5.2.4. collectorIPv4Address
Description:
An IPv4 address to which the Exporting Process sends Flow
information.
Abstract Data Type: ipv4Address
Data Type Semantics: identifier
ElementId: 211
Status: current
5.2.5. collectorIPv6Address
Description:
An IPv6 address to which the Exporting Process sends Flow
information.
Abstract Data Type: ipv6Address
Data Type Semantics: identifier
ElementId: 212
Status: current
5.2.6. exportInterface
Description:
The index of the interface from which IPFIX Messages sent by the
Exporting Process to a Collector leave the IPFIX Device. The
value matches the value of managed object 'ifIndex' as defined in
RFC 2863. Note that ifIndex values are not assigned statically to
an interface and that the interfaces may be renumbered every time
the device's management system is re-initialized, as specified in
RFC 2863.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 213
Status: current
Reference:
See RFC 2863 for the definition of the ifIndex object.
Quittek, et al. Standards Track [Page 25]
RFC 5102 IPFIX Information Model January 2008
5.2.7. exportProtocolVersion
Description:
The protocol version used by the Exporting Process for sending
Flow information. The protocol version is given by the value of
the Version Number field in the Message Header. The protocol
version is 10 for IPFIX and 9 for NetFlow version 9. A value of 0
indicates that no export protocol is in use.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 214
Status: current
Reference:
See the IPFIX protocol specification [RFC5101] for the definition
of the IPFIX Message Header.
See RFC 3954 for the definition of the NetFlow version 9 message
header.
5.2.8. exportTransportProtocol
Description:
The value of the protocol number used by the Exporting Process for
sending Flow information. The protocol number identifies the IP
packet payload type. Protocol numbers are defined in the IANA
Protocol Numbers registry.
In Internet Protocol version 4 (IPv4), this is carried in the
Protocol field. In Internet Protocol version 6 (IPv6), this is
carried in the Next Header field in the last extension header of
the packet.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 215
Status: current
Reference:
See RFC 791 for the specification of the IPv4 protocol field. See
RFC 2460 for the specification of the IPv6 protocol field. See
the list of protocol numbers assigned by IANA at
http://www.iana.org/assignments/protocol-numbers.
Quittek, et al. Standards Track [Page 26]
RFC 5102 IPFIX Information Model January 2008
5.2.9. collectorTransportPort
Description:
The destination port identifier to which the Exporting Process
sends Flow information. For the transport protocols UDP, TCP, and
SCTP, this is the destination port number. This field MAY also be
used for future transport protocols that have 16-bit source port
identifiers.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 216
Status: current
Reference:
See RFC 768 for the definition of the UDP destination port field.
See RFC 793 for the definition of the TCP destination port field.
See RFC 4960 for the definition of SCTP.
Additional information on defined UDP and TCP port numbers can be
found at http://www.iana.org/assignments/port-numbers.
5.2.10. flowKeyIndicator
Description:
This set of bit fields is used for marking the Information
Elements of a Data Record that serve as Flow Key. Each bit
represents an Information Element in the Data Record with the n-th
bit representing the n-th Information Element. A bit set to value
1 indicates that the corresponding Information Element is a Flow
Key of the reported Flow. A bit set to value 0 indicates that
this is not the case.
If the Data Record contains more than 64 Information Elements, the
corresponding Template SHOULD be designed such that all Flow Keys
are among the first 64 Information Elements, because the
flowKeyIndicator only contains 64 bits. If the Data Record
contains less than 64 Information Elements, then the bits in the
flowKeyIndicator for which no corresponding Information Element
exists MUST have the value 0.
Abstract Data Type: unsigned64
Data Type Semantics: flags
ElementId: 173
Status: current
Quittek, et al. Standards Track [Page 27]
RFC 5102 IPFIX Information Model January 2008
5.3. Metering and Exporting Process Statistics
Information Elements in this section describe statistics of the
Metering Process and/or the Exporting Process. The set of these
Information Elements is listed in the table below.
+-----+-----------------------------+-----+-------------------------+
| ID | Name | ID | Name |
+-----+-----------------------------+-----+-------------------------+
| 41 | exportedMessageTotalCount | 165 | ignoredOctetTotalCount |
| 40 | exportedOctetTotalCount | 166 | notSentFlowTotalCount |
| 42 | exportedFlowRecordTotalCount| 167 | notSentPacketTotalCount |
| 163 | observedFlowTotalCount | 168 | notSentOctetTotalCount |
| 164 | ignoredPacketTotalCount | | |
+-----+-----------------------------+-----+-------------------------+
5.3.1. exportedMessageTotalCount
Description:
The total number of IPFIX Messages that the Exporting Process has
sent since the Exporting Process (re-)initialization to a
particular Collecting Process. The reported number excludes the
IPFIX Message that carries the counter value. If this Information
Element is sent to a particular Collecting Process, then by
default it specifies the number of IPFIX Messages sent to this
Collecting Process.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 41
Status: current
Units: messages
5.3.2. exportedOctetTotalCount
Description:
The total number of octets that the Exporting Process has sent
since the Exporting Process (re-)initialization to a particular
Collecting Process. The value of this Information Element is
calculated by summing up the IPFIX Message Header length values of
all IPFIX Messages that were successfully sent to the Collecting
Process. The reported number excludes octets in the IPFIX Message
that carries the counter value. If this Information Element is
sent to a particular Collecting Process, then by default it
specifies the number of octets sent to this Collecting Process.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 40
Status: current
Quittek, et al. Standards Track [Page 28]
RFC 5102 IPFIX Information Model January 2008
Units: octets
5.3.3. exportedFlowRecordTotalCount
Description:
The total number of Flow Records that the Exporting Process has
sent as Data Records since the Exporting Process
(re-)initialization to a particular Collecting Process. The
reported number excludes Flow Records in the IPFIX Message that
carries the counter value. If this Information Element is sent to
a particular Collecting Process, then by default it specifies the
number of Flow Records sent to this process.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 42
Status: current
Units: flows
5.3.4. observedFlowTotalCount
Description:
The total number of Flows observed in the Observation Domain since
the Metering Process (re-)initialization for this Observation
Point.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 163
Status: current
Units: flows
5.3.5. ignoredPacketTotalCount
Description:
The total number of observed IP packets that the Metering Process
did not process since the (re-)initialization of the Metering
Process.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 164
Status: current
Units: packets
Quittek, et al. Standards Track [Page 29]
RFC 5102 IPFIX Information Model January 2008
5.3.6. ignoredOctetTotalCount
Description:
The total number of octets in observed IP packets (including the
IP header) that the Metering Process did not process since the
(re-)initialization of the Metering Process.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 165
Status: current
Units: octets
5.3.7. notSentFlowTotalCount
Description:
The total number of Flow Records that were generated by the
Metering Process and dropped by the Metering Process or by the
Exporting Process instead of being sent to the Collecting Process.
There are several potential reasons for this including resource
shortage and special Flow export policies.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 166
Status: current
Units: flows
5.3.8. notSentPacketTotalCount
Description:
The total number of packets in Flow Records that were generated by
the Metering Process and dropped by the Metering Process or by the
Exporting Process instead of being sent to the Collecting Process.
There are several potential reasons for this including resource
shortage and special Flow export policies.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 167
Status: current
Units: packets
Quittek, et al. Standards Track [Page 30]
RFC 5102 IPFIX Information Model January 2008
5.3.9. notSentOctetTotalCount
Description:
The total number of octets in packets in Flow Records that were
generated by the Metering Process and dropped by the Metering
Process or by the Exporting Process instead of being sent to the
Collecting Process. There are several potential reasons for this
including resource shortage and special Flow export policies.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 168
Status: current
Units: octets
5.4. IP Header Fields
Information Elements in this section indicate values of IP header
fields or are derived from IP header field values in combination with
further information.
+-----+----------------------------+-----+--------------------------+
| ID | Name | ID | Name |
+-----+----------------------------+-----+--------------------------+
| 60 | ipVersion | 193 | nextHeaderIPv6 |
| 8 | sourceIPv4Address | 195 | ipDiffServCodePoint |
| 27 | sourceIPv6Address | 196 | ipPrecedence |
| 9 | sourceIPv4PrefixLength | 5 | ipClassOfService |
| 29 | sourceIPv6PrefixLength | 55 | postIpClassOfService |
| 44 | sourceIPv4Prefix | 31 | flowLabelIPv6 |
| 170 | sourceIPv6Prefix | 206 | isMulticast |
| 12 | destinationIPv4Address | 54 | fragmentIdentification |
| 28 | destinationIPv6Address | 88 | fragmentOffset |
| 13 | destinationIPv4PrefixLength| 197 | fragmentFlags |
| 30 | destinationIPv6PrefixLength| 189 | ipHeaderLength |
| 45 | destinationIPv4Prefix | 207 | ipv4IHL |
| 169 | destinationIPv6Prefix | 190 | totalLengthIPv4 |
| 192 | ipTTL | 224 | ipTotalLength |
| 4 | protocolIdentifier | 191 | payloadLengthIPv6 |
+-----+----------------------------+-----+--------------------------+
5.4.1. ipVersion
Description:
The IP version field in the IP packet header.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 60
Status: current
Quittek, et al. Standards Track [Page 31]
RFC 5102 IPFIX Information Model January 2008
Reference:
See RFC 791 for the definition of the version field in the IPv4
packet header. See RFC 2460 for the definition of the version
field in the IPv6 packet header. Additional information on
defined version numbers can be found at
http://www.iana.org/assignments/version-numbers.
5.4.2. sourceIPv4Address
Description:
The IPv4 source address in the IP packet header.
Abstract Data Type: ipv4Address
Data Type Semantics: identifier
ElementId: 8
Status: current
Reference:
See RFC 791 for the definition of the IPv4 source address field.
5.4.3. sourceIPv6Address
Description:
The IPv6 source address in the IP packet header.
Abstract Data Type: ipv6Address
Data Type Semantics: identifier
ElementId: 27
Status: current
Reference:
See RFC 2460 for the definition of the Source Address field in the
IPv6 header.
5.4.4. sourceIPv4PrefixLength
Description:
The number of contiguous bits that are relevant in the
sourceIPv4Prefix Information Element.
Abstract Data Type: unsigned8
ElementId: 9
Status: current
Units: bits
Range: The valid range is 0-32.
Quittek, et al. Standards Track [Page 32]
RFC 5102 IPFIX Information Model January 2008
5.4.5. sourceIPv6PrefixLength
Description:
The number of contiguous bits that are relevant in the
sourceIPv6Prefix Information Element.
Abstract Data Type: unsigned8
ElementId: 29
Status: current
Units: bits
Range: The valid range is 0-128.
5.4.6. sourceIPv4Prefix
Description:
IPv4 source address prefix.
Abstract Data Type: ipv4Address
ElementId: 44
Status: current
5.4.7. sourceIPv6Prefix
Description:
IPv6 source address prefix.
Abstract Data Type: ipv6Address
ElementId: 170
Status: current
5.4.8. destinationIPv4Address
Description:
The IPv4 destination address in the IP packet header.
Abstract Data Type: ipv4Address
Data Type Semantics: identifier
ElementId: 12
Status: current
Reference:
See RFC 791 for the definition of the IPv4 destination address
field.
Quittek, et al. Standards Track [Page 33]
RFC 5102 IPFIX Information Model January 2008
5.4.9. destinationIPv6Address
Description:
The IPv6 destination address in the IP packet header.
Abstract Data Type: ipv6Address
Data Type Semantics: identifier
ElementId: 28
Status: current
Reference:
See RFC 2460 for the definition of the Destination Address field
in the IPv6 header.
5.4.10. destinationIPv4PrefixLength
Description:
The number of contiguous bits that are relevant in the
destinationIPv4Prefix Information Element.
Abstract Data Type: unsigned8
ElementId: 13
Status: current
Units: bits
Range: The valid range is 0-32.
5.4.11. destinationIPv6PrefixLength
Description:
The number of contiguous bits that are relevant in the
destinationIPv6Prefix Information Element.
Abstract Data Type: unsigned8
ElementId: 30
Status: current
Units: bits
Range: The valid range is 0-128.
5.4.12. destinationIPv4Prefix
Description:
IPv4 destination address prefix.
Abstract Data Type: ipv4Address
ElementId: 45
Status: current
Quittek, et al. Standards Track [Page 34]
RFC 5102 IPFIX Information Model January 2008
5.4.13. destinationIPv6Prefix
Description:
IPv6 destination address prefix.
Abstract Data Type: ipv6Address
ElementId: 169
Status: current
5.4.14. ipTTL
Description:
For IPv4, the value of the Information Element matches the value
of the Time to Live (TTL) field in the IPv4 packet header. For
IPv6, the value of the Information Element matches the value of
the Hop Limit field in the IPv6 packet header.
Abstract Data Type: unsigned8
ElementId: 192
Status: current
Units: hops
Reference:
See RFC 791 for the definition of the IPv4 Time to Live field.
See RFC 2460 for the definition of the IPv6 Hop Limit field.
5.4.15. protocolIdentifier
Description:
The value of the protocol number in the IP packet header. The
protocol number identifies the IP packet payload type. Protocol
numbers are defined in the IANA Protocol Numbers registry. In
Internet Protocol version 4 (IPv4), this is carried in the
Protocol field. In Internet Protocol version 6 (IPv6), this is
carried in the Next Header field in the last extension header of
the packet.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 4
Status: current
Reference:
See RFC 791 for the specification of the IPv4 protocol field. See
RFC 2460 for the specification of the IPv6 protocol field. See
the list of protocol numbers assigned by IANA at
http://www.iana.org/assignments/protocol-numbers.
Quittek, et al. Standards Track [Page 35]
RFC 5102 IPFIX Information Model January 2008
5.4.16. nextHeaderIPv6
Description:
The value of the Next Header field of the IPv6 header. The value
identifies the type of the following IPv6 extension header or of
the following IP payload. Valid values are defined in the IANA
Protocol Numbers registry.
Abstract Data Type: unsigned8
ElementId: 193
Status: current
Reference:
See RFC 2460 for the definition of the IPv6 Next Header field.
See the list of protocol numbers assigned by IANA at
http://www.iana.org/assignments/protocol-numbers.
5.4.17. ipDiffServCodePoint
Description:
The value of a Differentiated Services Code Point (DSCP) encoded
in the Differentiated Services field. The Differentiated Services
field spans the most significant 6 bits of the IPv4 TOS field or
the IPv6 Traffic Class field, respectively.
This Information Element encodes only the 6 bits of the
Differentiated Services field. Therefore, its value may range
from 0 to 63.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 195
Status: current
Range: The valid range is 0-63.
Reference:
See RFC 3260 for the definition of the Differentiated Services
field. See RFC 1812 (Section 5.3.2) and RFC 791 for the
definition of the IPv4 TOS field. See RFC 2460 for the definition
of the IPv6 Traffic Class field.
5.4.18. ipPrecedence
Description:
The value of the IP Precedence. The IP Precedence value is
encoded in the first 3 bits of the IPv4 TOS field or the IPv6
Traffic Class field, respectively. This Information Element
encodes only these 3 bits. Therefore, its value may range from 0
to 7.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 196
Status: current
Quittek, et al. Standards Track [Page 36]
RFC 5102 IPFIX Information Model January 2008
Range: The valid range is 0-7.
Reference:
See RFC 1812 (Section 5.3.3) and RFC 791 for the definition of the
IP Precedence. See RFC 1812 (Section 5.3.2) and RFC 791 for the
definition of the IPv4 TOS field. See RFC 2460 for the definition
of the IPv6 Traffic Class field.
5.4.19. ipClassOfService
Description:
For IPv4 packets, this is the value of the TOS field in the IPv4
packet header. For IPv6 packets, this is the value of the Traffic
Class field in the IPv6 packet header.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 5
Status: current
Reference:
See RFC 1812 (Section 5.3.2) and RFC 791 for the definition of the
IPv4 TOS field. See RFC 2460 for the definition of the IPv6
Traffic Class field.
5.4.20. postIpClassOfService
Description:
The definition of this Information Element is identical to the
definition of Information Element 'ipClassOfService', except that
it reports a potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 55
Status: current
Reference:
See RFC 791 for the definition of the IPv4 TOS field. See RFC
2460 for the definition of the IPv6 Traffic Class field. See RFC
3234 for the definition of middleboxes.
Quittek, et al. Standards Track [Page 37]
RFC 5102 IPFIX Information Model January 2008
5.4.21. flowLabelIPv6
Description:
The value of the IPv6 Flow Label field in the IP packet header.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 31
Status: current
Reference:
See RFC 2460 for the definition of the Flow Label field in the
IPv6 packet header.
5.4.22. isMulticast
Description:
If the IP destination address is not a reserved multicast address,
then the value of all bits of the octet (including the reserved
ones) is zero.
The first bit of this octet is set to 1 if the Version field of
the IP header has the value 4 and if the Destination Address field
contains a reserved multicast address in the range from 224.0.0.0
to 239.255.255.255. Otherwise, this bit is set to 0. The second
and third bits of this octet are reserved for future use.
The remaining bits of the octet are only set to values other than
zero if the IP Destination Address is a reserved IPv6 multicast
address. Then the fourth bit of the octet is set to the value of
the T flag in the IPv6 multicast address and the remaining four
bits are set to the value of the scope field in the IPv6 multicast
address.
0 1 2 3 4 5 6 7
+------+------+------+------+------+------+------+------+
| MCv4 | RES. | RES. | T | IPv6 multicast scope |
+------+------+------+------+------+------+------+------+
Bit 0: set to 1 if IPv4 multicast
Bits 1-2: reserved for future use
Bit 4: set to value of T flag, if IPv6 multicast
Bits 4-7: set to value of multicast scope if IPv6 multicast
Abstract Data Type: unsigned8
Data Type Semantics: flags
ElementId: 206
Status: current
Quittek, et al. Standards Track [Page 38]
RFC 5102 IPFIX Information Model January 2008
Reference:
See RFC 1112 for the specification of reserved IPv4 multicast
addresses. See RFC 4291 for the specification of reserved IPv6
multicast addresses and the definition of the T flag and the IPv6
multicast scope.
5.4.23. fragmentIdentification
Description:
The value of the Identification field in the IPv4 packet header or
in the IPv6 Fragment header, respectively. The value is 0 for
IPv6 if there is no fragment header.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 54
Status: current
Reference:
See RFC 791 for the definition of the IPv4 Identification field.
See RFC 2460 for the definition of the Identification field in the
IPv6 Fragment header.
5.4.24. fragmentOffset
Description:
The value of the IP fragment offset field in the IPv4 packet
header or the IPv6 Fragment header, respectively. The value is 0
for IPv6 if there is no fragment header.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 88
Status: current
Reference:
See RFC 791 for the specification of the fragment offset in the
IPv4 header. See RFC 2460 for the specification of the fragment
offset in the IPv6 Fragment header.
5.4.25. fragmentFlags
Description:
Fragmentation properties indicated by flags in the IPv4 packet
header or the IPv6 Fragment header, respectively.
Bit 0: (RS) Reserved.
The value of this bit MUST be 0 until specified
otherwise.
Quittek, et al. Standards Track [Page 39]
RFC 5102 IPFIX Information Model January 2008
Bit 1: (DF) 0 = May Fragment, 1 = Don't Fragment.
Corresponds to the value of the DF flag in the
IPv4 header. Will always be 0 for IPv6 unless
a "don't fragment" feature is introduced to IPv6.
Bit 2: (MF) 0 = Last Fragment, 1 = More Fragments.
Corresponds to the MF flag in the IPv4 header
or to the M flag in the IPv6 Fragment header,
respectively. The value is 0 for IPv6 if there
is no fragment header.
Bits 3-7: (DC) Don't Care.
The values of these bits are irrelevant.
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| R | D | M | D | D | D | D | D |
| S | F | F | C | C | C | C | C |
+---+---+---+---+---+---+---+---+
Abstract Data Type: unsigned8
Data Type Semantics: flags
ElementId: 197
Status: current
Reference:
See RFC 791 for the specification of the IPv4 fragment flags. See
RFC 2460 for the specification of the IPv6 Fragment header.
5.4.26. ipHeaderLength
Description:
The length of the IP header. For IPv6, the value of this
Information Element is 40.
Abstract Data Type: unsigned8
ElementId: 189
Status: current
Units: octets
Reference:
See RFC 791 for the specification of the IPv4 header. See RFC
2460 for the specification of the IPv6 header.
5.4.27. ipv4IHL
Description:
The value of the Internet Header Length (IHL) field in the IPv4
header. It specifies the length of the header in units of 4
octets. Please note that its unit is different from most of the
other Information Elements reporting length values.
Quittek, et al. Standards Track [Page 40]
RFC 5102 IPFIX Information Model January 2008
Abstract Data Type: unsigned8
ElementId: 207
Status: current
Units: 4 octets
Reference:
See RFC 791 for the specification of the IPv4 header.
5.4.28. totalLengthIPv4
Description:
The total length of the IPv4 packet.
Abstract Data Type: unsigned16
ElementId: 190
Status: current
Units: octets
Reference:
See RFC 791 for the specification of the IPv4 total length.
5.4.29. ipTotalLength
Description:
The total length of the IP packet.
Abstract Data Type: unsigned64
ElementId: 224
Status: current
Units: octets
Reference:
See RFC 791 for the specification of the IPv4 total length. See
RFC 2460 for the specification of the IPv6 payload length. See
RFC 2675 for the specification of the IPv6 jumbo payload length.
5.4.30. payloadLengthIPv6
Description:
This Information Element reports the value of the Payload Length
field in the IPv6 header. Note that IPv6 extension headers belong
to the payload. Also note that in case of a jumbo payload option
the value of the Payload Length field in the IPv6 header is zero
and so will be the value reported by this Information Element.
Abstract Data Type: unsigned16
ElementId: 191
Status: current
Units: octets
Reference:
See RFC 2460 for the specification of the IPv6 payload length.
See RFC 2675 for the specification of the IPv6 jumbo payload
option.
Quittek, et al. Standards Track [Page 41]
RFC 5102 IPFIX Information Model January 2008
5.5. Transport Header Fields
The set of Information Elements related to transport header fields
and length includes the Information Elements listed in the table
below.
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 7 | sourceTransportPort | 238 | tcpWindowScale |
| 11 | destinationTransportPort | 187 | tcpUrgentPointer |
| 180 | udpSourcePort | 188 | tcpHeaderLength |
| 181 | udpDestinationPort | 32 | icmpTypeCodeIPv4 |
| 205 | udpMessageLength | 176 | icmpTypeIPv4 |
| 182 | tcpSourcePort | 177 | icmpCodeIPv4 |
| 183 | tcpDestinationPort | 139 | icmpTypeCodeIPv6 |
| 184 | tcpSequenceNumber | 178 | icmpTypeIPv6 |
| 185 | tcpAcknowledgementNumber | 179 | icmpCodeIPv6 |
| 186 | tcpWindowSize | 33 | igmpType |
+-----+---------------------------+-----+---------------------------+
5.5.1. sourceTransportPort
Description:
The source port identifier in the transport header. For the
transport protocols UDP, TCP, and SCTP, this is the source port
number given in the respective header. This field MAY also be
used for future transport protocols that have 16-bit source port
identifiers.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 7
Status: current
Reference:
See RFC 768 for the definition of the UDP source port field. See
RFC 793 for the definition of the TCP source port field. See RFC
4960 for the definition of SCTP.
Additional information on defined UDP and TCP port numbers can be
found at http://www.iana.org/assignments/port-numbers.
5.5.2. destinationTransportPort
Description:
The destination port identifier in the transport header. For the
transport protocols UDP, TCP, and SCTP, this is the destination
port number given in the respective header. This field MAY also
be used for future transport protocols that have 16-bit
destination port identifiers.
Quittek, et al. Standards Track [Page 42]
RFC 5102 IPFIX Information Model January 2008
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 11
Status: current
Reference:
See RFC 768 for the definition of the UDP destination port field.
See RFC 793 for the definition of the TCP destination port field.
See RFC 4960 for the definition of SCTP. Additional information
on defined UDP and TCP port numbers can be found at
http://www.iana.org/assignments/port-numbers.
5.5.3. udpSourcePort
Description:
The source port identifier in the UDP header.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 180
Status: current
Reference:
See RFC 768 for the definition of the UDP source port field.
Additional information on defined UDP port numbers can be found at
http://www.iana.org/assignments/port-numbers.
5.5.4. udpDestinationPort
Description:
The destination port identifier in the UDP header.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 181
Status: current
Reference:
See RFC 768 for the definition of the UDP destination port field.
Additional information on defined UDP port numbers can be found at
http://www.iana.org/assignments/port-numbers.
5.5.5. udpMessageLength
Description:
The value of the Length field in the UDP header.
Abstract Data Type: unsigned16
ElementId: 205
Status: current
Units: octets
Reference:
See RFC 768 for the specification of the UDP header.
Quittek, et al. Standards Track [Page 43]
RFC 5102 IPFIX Information Model January 2008
5.5.6. tcpSourcePort
Description:
The source port identifier in the TCP header.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 182
Status: current
Reference:
See RFC 793 for the definition of the TCP source port field.
Additional information on defined TCP port numbers can be found at
http://www.iana.org/assignments/port-numbers.
5.5.7. tcpDestinationPort
Description:
The destination port identifier in the TCP header.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 183
Status: current
Reference:
See RFC 793 for the definition of the TCP source port field.
Additional information on defined TCP port numbers can be found at
http://www.iana.org/assignments/port-numbers.
5.5.8. tcpSequenceNumber
Description:
The sequence number in the TCP header.
Abstract Data Type: unsigned32
ElementId: 184
Status: current
Reference:
See RFC 793 for the definition of the TCP sequence number.
5.5.9. tcpAcknowledgementNumber
Description:
The acknowledgement number in the TCP header.
Abstract Data Type: unsigned32
ElementId: 185
Status: current
Reference:
See RFC 793 for the definition of the TCP acknowledgement number.
Quittek, et al. Standards Track [Page 44]
RFC 5102 IPFIX Information Model January 2008
5.5.10. tcpWindowSize
Description:
The window field in the TCP header. If the TCP window scale is
supported, then TCP window scale must be known to fully interpret
the value of this information.
Abstract Data Type: unsigned16
ElementId: 186
Status: current
Reference:
See RFC 793 for the definition of the TCP window field. See RFC
1323 for the definition of the TCP window scale.
5.5.11. tcpWindowScale
Description:
The scale of the window field in the TCP header.
Abstract Data Type: unsigned16
ElementId: 238
Status: current
Reference:
See RFC 1323 for the definition of the TCP window scale.
5.5.12. tcpUrgentPointer
Description:
The urgent pointer in the TCP header.
Abstract Data Type: unsigned16
ElementId: 187
Status: current
Reference:
See RFC 793 for the definition of the TCP urgent pointer.
5.5.13. tcpHeaderLength
Description:
The length of the TCP header. Note that the value of this
Information Element is different from the value of the Data Offset
field in the TCP header. The Data Offset field indicates the
length of the TCP header in units of 4 octets. This Information
Elements specifies the length of the TCP header in units of
octets.
Abstract Data Type: unsigned8
ElementId: 188
Status: current
Units: octets
Reference:
See RFC 793 for the definition of the TCP header.
Quittek, et al. Standards Track [Page 45]
RFC 5102 IPFIX Information Model January 2008
5.5.14. icmpTypeCodeIPv4
Description:
Type and Code of the IPv4 ICMP message. The combination of both
values is reported as (ICMP type * 256) + ICMP code.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 32
Status: current
Reference:
See RFC 792 for the definition of the IPv4 ICMP type and code
fields.
5.5.15. icmpTypeIPv4
Description:
Type of the IPv4 ICMP message.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 176
Status: current
Reference:
See RFC 792 for the definition of the IPv4 ICMP type field.
5.5.16. icmpCodeIPv4
Description:
Code of the IPv4 ICMP message.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 177
Status: current
Reference:
See RFC 792 for the definition of the IPv4 ICMP code field.
5.5.17. icmpTypeCodeIPv6
Description:
Type and Code of the IPv6 ICMP message. The combination of both
values is reported as (ICMP type * 256) + ICMP code.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 139
Status: current
Reference:
See RFC 4443 for the definition of the IPv6 ICMP type and code
fields.
Quittek, et al. Standards Track [Page 46]
RFC 5102 IPFIX Information Model January 2008
5.5.18. icmpTypeIPv6
Description:
Type of the IPv6 ICMP message.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 178
Status: current
Reference:
See RFC 4443 for the definition of the IPv6 ICMP type field.
5.5.19. icmpCodeIPv6
Description:
Code of the IPv6 ICMP message.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 179
Status: current
Reference:
See RFC 4443 for the definition of the IPv6 ICMP code field.
5.5.20. igmpType
Description:
The type field of the IGMP message.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 33
Status: current
Reference:
See RFC 3376 for the definition of the IGMP type field.
Quittek, et al. Standards Track [Page 47]
RFC 5102 IPFIX Information Model January 2008
5.6. Sub-IP Header Fields
The set of Information Elements related to Sub-IP header fields
includes the Information Elements listed in the table below.
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 56 | sourceMacAddress | 201 | mplsLabelStackLength |
| 81 | postSourceMacAddress | 194 | mplsPayloadLength |
| 58 | vlanId | 70 | mplsTopLabelStackSection |
| 59 | postVlanId | 71 | mplsLabelStackSection2 |
| 80 | destinationMacAddress | 72 | mplsLabelStackSection3 |
| 57 | postDestinationMacAddress | 73 | mplsLabelStackSection4 |
| 146 | wlanChannelId | 74 | mplsLabelStackSection5 |
| 147 | wlanSSID | 75 | mplsLabelStackSection6 |
| 200 | mplsTopLabelTTL | 76 | mplsLabelStackSection7 |
| 203 | mplsTopLabelExp | 77 | mplsLabelStackSection8 |
| 237 | postMplsTopLabelExp | 78 | mplsLabelStackSection9 |
| 202 | mplsLabelStackDepth | 79 | mplsLabelStackSection10 |
+-----+---------------------------+-----+---------------------------+
5.6.1. sourceMacAddress
Description:
The IEEE 802 source MAC address field.
Abstract Data Type: macAddress
Data Type Semantics: identifier
ElementId: 56
Status: current
Reference:
See IEEE.802-3.2002.
5.6.2. postSourceMacAddress
Description:
The definition of this Information Element is identical to the
definition of Information Element 'sourceMacAddress', except that
it reports a potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
Abstract Data Type: macAddress
Data Type Semantics: identifier
ElementId: 81
Status: current
Reference:
See IEEE.802-3.2002.
Quittek, et al. Standards Track [Page 48]
RFC 5102 IPFIX Information Model January 2008
5.6.3. vlanId
Description:
The IEEE 802.1Q VLAN identifier (VID) extracted from the Tag
Control Information field that was attached to the IP packet.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 58
Status: current
Reference:
See IEEE.802-1Q.2003.
5.6.4. postVlanId
Description:
The definition of this Information Element is identical to the
definition of Information Element 'vlanId', except that it reports
a potentially modified value caused by a middlebox function after
the packet passed the Observation Point.
Abstract Data Type: unsigned16
Data Type Semantics: identifier
ElementId: 59
Status: current
Reference:
See IEEE.802-1Q.2003.
5.6.5. destinationMacAddress
Description:
The IEEE 802 destination MAC address field.
Abstract Data Type: macAddress
Data Type Semantics: identifier
ElementId: 80
Status: current
Reference:
See IEEE.802-3.2002.
5.6.6. postDestinationMacAddress
Description:
The definition of this Information Element is identical to the
definition of Information Element 'destinationMacAddress', except
that it reports a potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
Abstract Data Type: macAddress
Data Type Semantics: identifier
ElementId: 57
Status: current
Quittek, et al. Standards Track [Page 49]
RFC 5102 IPFIX Information Model January 2008
Reference:
See IEEE.802-3.2002.
5.6.7. wlanChannelId
Description:
The identifier of the 802.11 (Wi-Fi) channel used.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 146
Status: current
Reference:
See IEEE.802-11.1999.
5.6.8. wlanSSID
Description:
The Service Set IDentifier (SSID) identifying an 802.11 (Wi-Fi)
network used. According to IEEE.802-11.1999, the SSID is encoded
into a string of up to 32 characters.
Abstract Data Type: string
ElementId: 147
Status: current
Reference:
See IEEE.802-11.1999.
5.6.9. mplsTopLabelTTL
Description:
The TTL field from the top MPLS label stack entry, i.e., the last
label that was pushed.
Abstract Data Type: unsigned8
ElementId: 200
Status: current
Units: hops
Reference:
See RFC 3032 for the specification of the TTL field.
Quittek, et al. Standards Track [Page 50]
RFC 5102 IPFIX Information Model January 2008
5.6.10. mplsTopLabelExp
Description:
The Exp field from the top MPLS label stack entry, i.e., the last
label that was pushed.
Bits 0-4: Don't Care, value is irrelevant.
Bits 5-7: MPLS Exp field.
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| don't care | Exp |
+---+---+---+---+---+---+---+---+
Abstract Data Type: unsigned8
Data Type Semantics: flags
ElementId: 203
Status: current
Reference:
See RFC 3032 for the specification of the Exp field. See RFC 3270
for usage of the Exp field.
5.6.11. postMplsTopLabelExp
Description:
The definition of this Information Element is identical to the
definition of Information Element 'mplsTopLabelExp', except that
it reports a potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
Abstract Data Type: unsigned8
Data Type Semantics: flags
ElementId: 237
Status: current
Reference:
See RFC 3032 for the specification of the Exp field. See RFC 3270
for usage of the Exp field.
5.6.12. mplsLabelStackDepth
Description:
The number of labels in the MPLS label stack.
Abstract Data Type: unsigned32
ElementId: 202
Status: current
Units: label stack entries
Reference:
See RFC 3032 for the specification of the MPLS label stack.
Quittek, et al. Standards Track [Page 51]
RFC 5102 IPFIX Information Model January 2008
5.6.13. mplsLabelStackLength
Description:
The length of the MPLS label stack in units of octets.
Abstract Data Type: unsigned32
ElementId: 201
Status: current
Units: octets
Reference:
See RFC 3032 for the specification of the MPLS label stack.
5.6.14. mplsPayloadLength
Description:
The size of the MPLS packet without the label stack.
Abstract Data Type: unsigned32
ElementId: 194
Status: current
Units: octets
Reference:
See RFC 3031 for the specification of MPLS packets. See RFC 3032
for the specification of the MPLS label stack.
5.6.15. mplsTopLabelStackSection
Description:
The Label, Exp, and S fields from the top MPLS label stack entry,
i.e., from the last label that was pushed. The size of this
Information Element is 3 octets.
0 1 2
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Label | Exp |S|
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Label: Label Value, 20 bits
Exp: Experimental Use, 3 bits
S: Bottom of Stack, 1 bit
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 70
Status: current
Reference:
See RFC 3032.
Quittek, et al. Standards Track [Page 52]
RFC 5102 IPFIX Information Model January 2008
5.6.16. mplsLabelStackSection2
Description:
The Label, Exp, and S fields from the label stack entry that was
pushed immediately before the label stack entry that would be
reported by mplsTopLabelStackSection. See the definition of
mplsTopLabelStackSection for further details. The size of this
Information Element is 3 octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 71
Status: current
Reference:
See RFC 3032.
5.6.17. mplsLabelStackSection3
Description:
The Label, Exp, and S fields from the label stack entry that was
pushed immediately before the label stack entry that would be
reported by mplsLabelStackSection2. See the definition of
mplsTopLabelStackSection for further details. The size of this
Information Element is 3 octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 72
Status: current
Reference:
See RFC 3032.
5.6.18. mplsLabelStackSection4
Description:
The Label, Exp, and S fields from the label stack entry that was
pushed immediately before the label stack entry that would be
reported by mplsLabelStackSection3. See the definition of
mplsTopLabelStackSection for further details. The size of this
Information Element is 3 octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 73
Status: current
Reference:
See RFC 3032.
Quittek, et al. Standards Track [Page 53]
RFC 5102 IPFIX Information Model January 2008
5.6.19. mplsLabelStackSection5
Description:
The Label, Exp, and S fields from the label stack entry that was
pushed immediately before the label stack entry that would be
reported by mplsLabelStackSection4. See the definition of
mplsTopLabelStackSection for further details. The size of this
Information Element is 3 octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 74
Status: current
Reference:
See RFC 3032.
5.6.20. mplsLabelStackSection6
Description:
The Label, Exp, and S fields from the label stack entry that was
pushed immediately before the label stack entry that would be
reported by mplsLabelStackSection5. See the definition of
mplsTopLabelStackSection for further details. The size of this
Information Element is 3 octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 75
Status: current
Reference:
See RFC 3032.
5.6.21. mplsLabelStackSection7
Description:
The Label, Exp, and S fields from the label stack entry that was
pushed immediately before the label stack entry that would be
reported by mplsLabelStackSection6. See the definition of
mplsTopLabelStackSection for further details. The size of this
Information Element is 3 octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 76
Status: current
Reference:
See RFC 3032.
Quittek, et al. Standards Track [Page 54]
RFC 5102 IPFIX Information Model January 2008
5.6.22. mplsLabelStackSection8
Description:
The Label, Exp, and S fields from the label stack entry that was
pushed immediately before the label stack entry that would be
reported by mplsLabelStackSection7. See the definition of
mplsTopLabelStackSection for further details. The size of this
Information Element is 3 octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 77
Status: current
Reference:
See RFC 3032.
5.6.23. mplsLabelStackSection9
Description:
The Label, Exp, and S fields from the label stack entry that was
pushed immediately before the label stack entry that would be
reported by mplsLabelStackSection8. See the definition of
mplsTopLabelStackSection for further details. The size of this
Information Element is 3 octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 78
Status: current
Reference:
See RFC 3032.
5.6.24. mplsLabelStackSection10
Description:
The Label, Exp, and S fields from the label stack entry that was
pushed immediately before the label stack entry that would be
reported by mplsLabelStackSection9. See the definition of
mplsTopLabelStackSection for further details. The size of this
Information Element is 3 octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 79
Status: current
Reference:
See RFC 3032.
Quittek, et al. Standards Track [Page 55]
RFC 5102 IPFIX Information Model January 2008
5.7. Derived Packet Properties
The set of Information Elements derived from packet properties (for
example, values of header fields) includes the Information Elements
listed in the table below.
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 204 | ipPayloadLength | 18 | bgpNextHopIPv4Address |
| 15 | ipNextHopIPv4Address | 63 | bgpNextHopIPv6Address |
| 62 | ipNextHopIPv6Address | 46 | mplsTopLabelType |
| 16 | bgpSourceAsNumber | 47 | mplsTopLabelIPv4Address |
| 17 | bgpDestinationAsNumber | 140 | mplsTopLabelIPv6Address |
| 128 | bgpNextAdjacentAsNumber | 90 | mplsVpnRouteDistinguisher |
| 129 | bgpPrevAdjacentAsNumber | | |
+-----+---------------------------+-----+---------------------------+
5.7.1. ipPayloadLength
Description:
The effective length of the IP payload. For IPv4 packets, the
value of this Information Element is the difference between the
total length of the IPv4 packet (as reported by Information
Element totalLengthIPv4) and the length of the IPv4 header (as
reported by Information Element headerLengthIPv4). For IPv6, the
value of the Payload Length field in the IPv6 header is reported
except in the case that the value of this field is zero and that
there is a valid jumbo payload option. In this case, the value of
the Jumbo Payload Length field in the jumbo payload option is
reported.
Abstract Data Type: unsigned32
ElementId: 204
Status: current
Units: octets
Reference:
See RFC 791 for the specification of IPv4 packets. See RFC 2460
for the specification of the IPv6 payload length. See RFC 2675
for the specification of the IPv6 jumbo payload length.
5.7.2. ipNextHopIPv4Address
Description:
The IPv4 address of the next IPv4 hop.
Abstract Data Type: ipv4Address
Data Type Semantics: identifier
ElementId: 15
Status: current
Quittek, et al. Standards Track [Page 56]
RFC 5102 IPFIX Information Model January 2008
5.7.3. ipNextHopIPv6Address
Description:
The IPv6 address of the next IPv6 hop.
Abstract Data Type: ipv6Address
Data Type Semantics: identifier
ElementId: 62
Status: current
5.7.4. bgpSourceAsNumber
Description:
The autonomous system (AS) number of the source IP address. If AS
path information for this Flow is only available as an unordered
AS set (and not as an ordered AS sequence), then the value of this
Information Element is 0.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 16
Status: current
Reference:
See RFC 4271 for a description of BGP-4, and see RFC 1930 for the
definition of the AS number.
5.7.5. bgpDestinationAsNumber
Description:
The autonomous system (AS) number of the destination IP address.
If AS path information for this Flow is only available as an
unordered AS set (and not as an ordered AS sequence), then the
value of this Information Element is 0.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 17
Status: current
Reference:
See RFC 4271 for a description of BGP-4, and see RFC 1930 for the
definition of the AS number.
5.7.6. bgpNextAdjacentAsNumber
Description:
The autonomous system (AS) number of the first AS in the AS path
to the destination IP address. The path is deduced by looking up
the destination IP address of the Flow in the BGP routing
information base. If AS path information for this Flow is only
available as an unordered AS set (and not as an ordered AS
sequence), then the value of this Information Element is 0.
Quittek, et al. Standards Track [Page 57]
RFC 5102 IPFIX Information Model January 2008
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 128
Status: current
Reference:
See RFC 4271 for a description of BGP-4, and see RFC 1930 for the
definition of the AS number.
5.7.7. bgpPrevAdjacentAsNumber
Description:
The autonomous system (AS) number of the last AS in the AS path
from the source IP address. The path is deduced by looking up the
source IP address of the Flow in the BGP routing information base.
If AS path information for this Flow is only available as an
unordered AS set (and not as an ordered AS sequence), then the
value of this Information Element is 0. In case of BGP asymmetry,
the bgpPrevAdjacentAsNumber might not be able to report the
correct value.
Abstract Data Type: unsigned32
Data Type Semantics: identifier
ElementId: 129
Status: current
Reference:
See RFC 4271 for a description of BGP-4, and see RFC 1930 for the
definition of the AS number.
5.7.8. bgpNextHopIPv4Address
Description:
The IPv4 address of the next (adjacent) BGP hop.
Abstract Data Type: ipv4Address
Data Type Semantics: identifier
ElementId: 18
Status: current
Reference:
See RFC 4271 for a description of BGP-4.
5.7.9. bgpNextHopIPv6Address
Description:
The IPv6 address of the next (adjacent) BGP hop.
Abstract Data Type: ipv6Address
Data Type Semantics: identifier
ElementId: 63
Status: current
Reference:
See RFC 4271 for a description of BGP-4.
Quittek, et al. Standards Track [Page 58]
RFC 5102 IPFIX Information Model January 2008
5.7.10. mplsTopLabelType
Description:
This field identifies the control protocol that
allocated the top-of-stack label. Initial values for this field
are listed below. Further values may be assigned by IANA in the
MPLS label type registry.
- 0x01 TE-MIDPT: Any TE tunnel mid-point or tail label
- 0x02 Pseudowire: Any PWE3 or Cisco AToM based label
- 0x03 VPN: Any label associated with VPN
- 0x04 BGP: Any label associated with BGP or BGP routing
- 0x05 LDP: Any label associated with dynamically assigned
labels using LDP
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 46
Status: current
Reference:
See RFC 3031 for the MPLS label structure. See RFC 4364 for the
association of MPLS labels with Virtual Private Networks (VPNs).
See RFC 4271 for BGP and BGP routing. See RFC 5036 for Label
Distribution Protocol (LDP). See the list of MPLS label types
assigned by IANA at
http://www.iana.org/assignments/mpls-label-values.
5.7.11. mplsTopLabelIPv4Address
Description:
The IPv4 address of the system that the MPLS top label will cause
this Flow to be forwarded to.
Abstract Data Type: ipv4Address
Data Type Semantics: identifier
ElementId: 47
Status: current
Reference:
See RFC 3031 for the association between MPLS labels and IP
addresses.
Quittek, et al. Standards Track [Page 59]
RFC 5102 IPFIX Information Model January 2008
5.7.12. mplsTopLabelIPv6Address
Description:
The IPv6 address of the system that the MPLS top label will cause
this Flow to be forwarded to.
Abstract Data Type: ipv6Address
Data Type Semantics: identifier
ElementId: 140
Status: current
Reference:
See RFC 3031 for the association between MPLS labels and IP
addresses.
5.7.13. mplsVpnRouteDistinguisher
Description:
The value of the VPN route distinguisher of a corresponding entry
in a VPN routing and forwarding table. Route distinguisher
ensures that the same address can be used in several different
MPLS VPNs and that it is possible for BGP to carry several
completely different routes to that address, one for each VPN.
According to RFC 4364, the size of mplsVpnRouteDistinguisher is 8
octets. However, in RFC 4382 an octet string with flexible length
was chosen for representing a VPN route distinguisher by object
MplsL3VpnRouteDistinguisher. This choice was made in order to be
open to future changes of the size. This idea was adopted when
choosing octetArray as abstract data type for this Information
Element. The maximum length of this Information Element is 256
octets.
Abstract Data Type: octetArray
Data Type Semantics: identifier
ElementId: 90
Status: current
Reference:
See RFC 4364 for the specification of the route distinguisher.
See RFC 4382 for the specification of the MPLS/BGP Layer 3 Virtual
Private Network (VPN) Management Information Base.
Quittek, et al. Standards Track [Page 60]
RFC 5102 IPFIX Information Model January 2008
5.8. Min/Max Flow Properties
Information Elements in this section are results of minimum or
maximum operations over all packets of a Flow.
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 25 | minimumIpTotalLength | 208 | ipv4Options |
| 26 | maximumIpTotalLength | 64 | ipv6ExtensionHeaders |
| 52 | minimumTTL | 6 | tcpControlBits |
| 53 | maximumTTL | 209 | tcpOptions |
+-----+---------------------------+-----+---------------------------+
5.8.1. minimumIpTotalLength
Description:
Length of the smallest packet observed for this Flow. The packet
length includes the IP header(s) length and the IP payload length.
Abstract Data Type: unsigned64
ElementId: 25
Status: current
Units: octets
Reference:
See RFC 791 for the specification of the IPv4 total length. See
RFC 2460 for the specification of the IPv6 payload length. See
RFC 2675 for the specification of the IPv6 jumbo payload length.
5.8.2. maximumIpTotalLength
Description:
Length of the largest packet observed for this Flow. The packet
length includes the IP header(s) length and the IP payload length.
Abstract Data Type: unsigned64
ElementId: 26
Status: current
Units: octets
Reference:
See RFC 791 for the specification of the IPv4 total length. See
RFC 2460 for the specification of the IPv6 payload length. See
RFC 2675 for the specification of the IPv6 jumbo payload length.
5.8.3. minimumTTL
Description:
Minimum TTL value observed for any packet in this Flow.
Quittek, et al. Standards Track [Page 61]
RFC 5102 IPFIX Information Model January 2008
Abstract Data Type: unsigned8
ElementId: 52
Status: current
Units: hops
Reference:
See RFC 791 for the definition of the IPv4 Time to Live field.
See RFC 2460 for the definition of the IPv6 Hop Limit field.
5.8.4. maximumTTL
Description:
Maximum TTL value observed for any packet in this Flow.
Abstract Data Type: unsigned8
ElementId: 53
Status: current
Units: hops
Reference:
See RFC 791 for the definition of the IPv4 Time to Live field.
See RFC 2460 for the definition of the IPv6 Hop Limit field.
5.8.5. ipv4Options
Description:
IPv4 options in packets of this Flow. The information is encoded
in a set of bit fields. For each valid IPv4 option type, there is
a bit in this set. The bit is set to 1 if any observed packet of
this Flow contains the corresponding IPv4 option type. Otherwise,
if no observed packet of this Flow contained the respective IPv4
option type, the value of the corresponding bit is 0. The list of
valid IPv4 options is maintained by IANA. Note that for
identifying an option not just the 5-bit Option Number, but all 8
bits of the Option Type need to match one of the IPv4 options
specified at http://www.iana.org/assignments/ip-parameters.
Options are mapped to bits according to their option numbers.
Option number X is mapped to bit X. The mapping is illustrated by
the figure below.
0 1 2 3 4 5 6 7
+------+------+------+------+------+------+------+------+
| EOOL | NOP | SEC | LSR | TS |E-SEC |CIPSO | RR | ...
+------+------+------+------+------+------+------+------+
8 9 10 11 12 13 14 15
+------+------+------+------+------+------+------+------+
... | SID | SSR | ZSU | MTUP | MTUR | FINN | VISA |ENCODE| ...
+------+------+------+------+------+------+------+------+
16 17 18 19 20 21 22 23
Quittek, et al. Standards Track [Page 62]
RFC 5102 IPFIX Information Model January 2008
+------+------+------+------+------+------+------+------+
... |IMITD | EIP | TR |ADDEXT|RTRALT| SDB |NSAPA | DPS | ...
+------+------+------+------+------+------+------+------+
24 25 26 27 28 29 30 31
+------+------+------+------+------+------+------+------+
... | UMP | QS | to be assigned by IANA | EXP | |
+------+------+------+------+------+------+------+------+
Type Option
Bit Value Name Reference
---+-----+-------+------------------------------------
0 0 EOOL End of Options List, RFC 791
1 1 NOP No Operation, RFC 791
2 130 SEC Security, RFC 1108
3 131 LSR Loose Source Route, RFC 791
4 68 TS Time Stamp, RFC 791
5 133 E-SEC Extended Security, RFC 1108
6 134 CIPSO Commercial Security
7 7 RR Record Route, RFC 791
8 136 SID Stream ID, RFC 791
9 137 SSR Strict Source Route, RFC 791
10 10 ZSU Experimental Measurement
11 11 MTUP (obsoleted) MTU Probe, RFC 1191
12 12 MTUR (obsoleted) MTU Reply, RFC 1191
13 205 FINN Experimental Flow Control
14 142 VISA Experimental Access Control
15 15 ENCODE
16 144 IMITD IMI Traffic Descriptor
17 145 EIP Extended Internet Protocol, RFC 1385
18 82 TR Traceroute, RFC 3193
19 147 ADDEXT Address Extension
20 148 RTRALT Router Alert, RFC 2113
21 149 SDB Selective Directed Broadcast
22 150 NSAPA NSAP Address
23 151 DPS Dynamic Packet State
24 152 UMP Upstream Multicast Pkt.
25 25 QS Quick-Start
30 30 EXP RFC3692-style Experiment
30 94 EXP RFC3692-style Experiment
30 158 EXP RFC3692-style Experiment
30 222 EXP RFC3692-style Experiment
... ... ... Further options numbers
may be assigned by IANA
Abstract Data Type: unsigned32
Data Type Semantics: flags
ElementId: 208
Quittek, et al. Standards Track [Page 63]
RFC 5102 IPFIX Information Model January 2008
Status: current
Reference:
See RFC 791 for the definition of IPv4 options. See the list of
IPv4 option numbers assigned by IANA at
http://www.iana.org/assignments/ip-parameters.
5.8.6. ipv6ExtensionHeaders
Description:
IPv6 extension headers observed in packets of this Flow. The
information is encoded in a set of bit fields. For each IPv6
option header, there is a bit in this set. The bit is set to 1 if
any observed packet of this Flow contains the corresponding IPv6
extension header. Otherwise, if no observed packet of this Flow
contained the respective IPv6 extension header, the value of the
corresponding bit is 0.
0 1 2 3 4 5 6 7
+-----+-----+-----+-----+-----+-----+-----+-----+
| Res | FRA1| RH | FRA0| UNK | Res | HOP | DST | ...
+-----+-----+-----+-----+-----+-----+-----+-----+
8 9 10 11 12 13 14 15
+-----+-----+-----+-----+-----+-----+-----+-----+
... | PAY | AH | ESP | Reserved | ...
+-----+-----+-----+-----+-----+-----+-----+-----+
16 17 18 19 20 21 22 23
+-----+-----+-----+-----+-----+-----+-----+-----+
... | Reserved | ...
+-----+-----+-----+-----+-----+-----+-----+-----+
24 25 26 27 28 29 30 31
+-----+-----+-----+-----+-----+-----+-----+-----+
... | Reserved |
+-----+-----+-----+-----+-----+-----+-----+-----+
Bit IPv6 Option Description
0, Res Reserved
1, FRA1 44 Fragmentation header - not first fragment
2, RH 43 Routing header
3, FRA0 44 Fragment header - first fragment
4, UNK Unknown Layer 4 header
(compressed, encrypted, not supported)
5, Res Reserved
6, HOP 0 Hop-by-hop option header
7, DST 60 Destination option header
Quittek, et al. Standards Track [Page 64]
RFC 5102 IPFIX Information Model January 2008
8, PAY 108 Payload compression header
9, AH 51 Authentication Header
10, ESP 50 Encrypted security payload
11 to 31 Reserved
Abstract Data Type: unsigned32
Data Type Semantics: flags
ElementId: 64
Status: current
Reference:
See RFC 2460 for the general definition of IPv6 extension headers
and for the specification of the hop-by-hop options header, the
routing header, the fragment header, and the destination options
header. See RFC 4302 for the specification of the authentication
header. See RFC 4303 for the specification of the encapsulating
security payload.
5.8.7. tcpControlBits
Description:
TCP control bits observed for packets of this Flow. The
information is encoded in a set of bit fields. For each TCP
control bit, there is a bit in this set. A bit is set to 1 if any
observed packet of this Flow has the corresponding TCP control bit
set to 1. A value of 0 for a bit indicates that the corresponding
bit was not set in any of the observed packets of this Flow.
0 1 2 3 4 5 6 7
+-----+-----+-----+-----+-----+-----+-----+-----+
| Reserved | URG | ACK | PSH | RST | SYN | FIN |
+-----+-----+-----+-----+-----+-----+-----+-----+
Reserved: Reserved for future use by TCP. Must be zero.
URG: Urgent Pointer field significant
ACK: Acknowledgment field significant
PSH: Push Function
RST: Reset the connection
SYN: Synchronize sequence numbers
FIN: No more data from sender
Abstract Data Type: unsigned8
Data Type Semantics: flags
ElementId: 6
Status: current
Reference:
See RFC 793 for the definition of the TCP control bits in the TCP
header.
Quittek, et al. Standards Track [Page 65]
RFC 5102 IPFIX Information Model January 2008
5.8.8. tcpOptions
Description:
TCP options in packets of this Flow. The information is encoded
in a set of bit fields. For each TCP option, there is a bit in
this set. The bit is set to 1 if any observed packet of this Flow
contains the corresponding TCP option. Otherwise, if no observed
packet of this Flow contained the respective TCP option, the value
of the corresponding bit is 0.
Options are mapped to bits according to their option numbers.
Option number X is mapped to bit X. TCP option numbers are
maintained by IANA.
0 1 2 3 4 5 6 7
+-----+-----+-----+-----+-----+-----+-----+-----+
| 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | ...
+-----+-----+-----+-----+-----+-----+-----+-----+
8 9 10 11 12 13 14 15
+-----+-----+-----+-----+-----+-----+-----+-----+
... | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 |...
+-----+-----+-----+-----+-----+-----+-----+-----+
16 17 18 19 20 21 22 23
+-----+-----+-----+-----+-----+-----+-----+-----+
... | 16 | 17 | 18 | 19 | 20 | 21 | 22 | 23 |...
+-----+-----+-----+-----+-----+-----+-----+-----+
. . .
56 57 58 59 60 61 62 63
+-----+-----+-----+-----+-----+-----+-----+-----+
... | 56 | 57 | 58 | 59 | 60 | 61 | 62 | 63 |
+-----+-----+-----+-----+-----+-----+-----+-----+
Abstract Data Type: unsigned64
Data Type Semantics: flags
ElementId: 209
Status: current
Reference:
See RFC 793 for the definition of TCP options. See the list of
TCP option numbers assigned by IANA at
http://www.iana.org/assignments/tcp-parameters.
Quittek, et al. Standards Track [Page 66]
RFC 5102 IPFIX Information Model January 2008
5.9. Flow Timestamps
Information Elements in this section are timestamps of events.
Timestamps flowStartSeconds, flowEndSeconds, flowStartMilliseconds,
flowEndMilliseconds, flowStartMicroseconds, flowEndMicroseconds,
flowStartNanoseconds, flowEndNanoseconds, and
systemInitTimeMilliseconds are absolute and have a well-defined fixed
time base, such as, for example, the number of seconds since 0000 UTC
Jan 1st 1970.
Timestamps flowStartDeltaMicroseconds and flowEndDeltaMicroseconds
are relative timestamps only valid within the scope of a single IPFIX
Message. They contain the negative time offsets relative to the
export time specified in the IPFIX Message Header. The maximum time
offset that can be encoded by these delta counters is 1 hour, 11
minutes, and 34.967295 seconds.
Timestamps flowStartSysUpTime and flowEndSysUpTime are relative
timestamps indicating the time relative to the last (re-
)initialization of the IPFIX Device. For reporting the time of the
last (re-)initialization, systemInitTimeMilliseconds can be reported,
for example, in Data Records defined by Option Templates.
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 150 | flowStartSeconds | 156 | flowStartNanoseconds |
| 151 | flowEndSeconds | 157 | flowEndNanoseconds |
| 152 | flowStartMilliseconds | 158 | flowStartDeltaMicroseconds|
| 153 | flowEndMilliseconds | 159 | flowEndDeltaMicroseconds |
| 154 | flowStartMicroseconds | 160 | systemInitTimeMilliseconds|
| 155 | flowEndMicroseconds | 22 | flowStartSysUpTime |
| | | 21 | flowEndSysUpTime |
+-----+---------------------------+-----+---------------------------+
5.9.1. flowStartSeconds
Description:
The absolute timestamp of the first packet of this Flow.
Abstract Data Type: dateTimeSeconds
ElementId: 150
Status: current
Units: seconds
Quittek, et al. Standards Track [Page 67]
RFC 5102 IPFIX Information Model January 2008
5.9.2. flowEndSeconds
Description:
The absolute timestamp of the last packet of this Flow.
Abstract Data Type: dateTimeSeconds
ElementId: 151
Status: current
Units: seconds
5.9.3. flowStartMilliseconds
Description:
The absolute timestamp of the first packet of this Flow.
Abstract Data Type: dateTimeMilliseconds
ElementId: 152
Status: current
Units: milliseconds
5.9.4. flowEndMilliseconds
Description:
The absolute timestamp of the last packet of this Flow.
Abstract Data Type: dateTimeMilliseconds
ElementId: 153
Status: current
Units: milliseconds
5.9.5. flowStartMicroseconds
Description:
The absolute timestamp of the first packet of this Flow.
Abstract Data Type: dateTimeMicroseconds
ElementId: 154
Status: current
Units: microseconds
5.9.6. flowEndMicroseconds
Description:
The absolute timestamp of the last packet of this Flow.
Abstract Data Type: dateTimeMicroseconds
ElementId: 155
Status: current
Units: microseconds
Quittek, et al. Standards Track [Page 68]
RFC 5102 IPFIX Information Model January 2008
5.9.7. flowStartNanoseconds
Description:
The absolute timestamp of the first packet of this Flow.
Abstract Data Type: dateTimeNanoseconds
ElementId: 156
Status: current
Units: nanoseconds
5.9.8. flowEndNanoseconds
Description:
The absolute timestamp of the last packet of this Flow.
Abstract Data Type: dateTimeNanoseconds
ElementId: 157
Status: current
Units: nanoseconds
5.9.9. flowStartDeltaMicroseconds
Description:
This is a relative timestamp only valid within the scope of a
single IPFIX Message. It contains the negative time offset of the
first observed packet of this Flow relative to the export time
specified in the IPFIX Message Header.
Abstract Data Type: unsigned32
ElementId: 158
Status: current
Units: microseconds
Reference:
See the IPFIX protocol specification [RFC5101] for the definition
of the IPFIX Message Header.
5.9.10. flowEndDeltaMicroseconds
Description:
This is a relative timestamp only valid within the scope of a
single IPFIX Message. It contains the negative time offset of the
last observed packet of this Flow relative to the export time
specified in the IPFIX Message Header.
Abstract Data Type: unsigned32
ElementId: 159
Status: current
Units: microseconds
Reference:
See the IPFIX protocol specification [RFC5101] for the
definition of the IPFIX Message Header.
Quittek, et al. Standards Track [Page 69]
RFC 5102 IPFIX Information Model January 2008
5.9.11. systemInitTimeMilliseconds
Description:
The absolute timestamp of the last (re-)initialization of the
IPFIX Device.
Abstract Data Type: dateTimeMilliseconds
ElementId: 160
Status: current
Units: milliseconds
5.9.12. flowStartSysUpTime
Description:
The relative timestamp of the first packet of this Flow. It
indicates the number of milliseconds since the last
(re-)initialization of the IPFIX Device (sysUpTime).
Abstract Data Type: unsigned32
ElementId: 22
Status: current
Units: milliseconds
5.9.13. flowEndSysUpTime
Description:
The relative timestamp of the last packet of this Flow. It
indicates the number of milliseconds since the last
(re-)initialization of the IPFIX Device (sysUpTime).
Abstract Data Type: unsigned32
ElementId: 21
Status: current
Units: milliseconds
5.10. Per-Flow Counters
Information Elements in this section are counters all having integer
values. Their values may change for every report they are used in.
They cannot serve as part of a Flow Key used for mapping packets to
Flows. However, potentially they can be used for selecting exported
Flows, for example, by only exporting Flows with more than a
threshold number of observed octets.
There are running counters and delta counters. Delta counters are
reset to zero each time their values are exported. Running counters
continue counting independently of the Exporting Process.
There are per-Flow counters and counters related to the Metering
Process and/or the Exporting Process. Per-Flow counters are Flow
properties that potentially change each time a packet belonging to
Quittek, et al. Standards Track [Page 70]
RFC 5102 IPFIX Information Model January 2008
the Flow is observed. The set of per-Flow counters includes the
Information Elements listed in the table below. Counters related to
the Metering Process and/or the Exporting Process are described in
Section 5.3.
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 1 | octetDeltaCount | 134 | droppedOctetTotalCount |
| 23 | postOctetDeltaCount | 135 | droppedPacketTotalCount |
| 198 | octetDeltaSumOfSquares | 19 | postMCastPacketDeltaCount |
| 85 | octetTotalCount | 20 | postMCastOctetDeltaCount |
| 171 | postOctetTotalCount | 174 | postMCastPacketTotalCount |
| 199 | octetTotalSumOfSquares | 175 | postMCastOctetTotalCount |
| 2 | packetDeltaCount | 218 | tcpSynTotalCount |
| 24 | postPacketDeltaCount | 219 | tcpFinTotalCount |
| 86 | packetTotalCount | 220 | tcpRstTotalCount |
| 172 | postPacketTotalCount | 221 | tcpPshTotalCount |
| 132 | droppedOctetDeltaCount | 222 | tcpAckTotalCount |
| 133 | droppedPacketDeltaCount | 223 | tcpUrgTotalCount |
+-----+---------------------------+-----+---------------------------+
5.10.1. octetDeltaCount
Description:
The number of octets since the previous report (if any) in
incoming packets for this Flow at the Observation Point. The
number of octets includes IP header(s) and IP payload.
Abstract Data Type: unsigned64
Data Type Semantics: deltaCounter
ElementId: 1
Status: current
Units: octets
5.10.2. postOctetDeltaCount
Description:
The definition of this Information Element is identical to the
definition of Information Element 'octetDeltaCount', except that
it reports a potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
Abstract Data Type: unsigned64
Data Type Semantics: deltaCounter
ElementId: 23
Status: current
Units: octets
Quittek, et al. Standards Track [Page 71]
RFC 5102 IPFIX Information Model January 2008
5.10.3. octetDeltaSumOfSquares
Description:
The sum of the squared numbers of octets per incoming packet since
the previous report (if any) for this Flow at the Observation
Point. The number of octets includes IP header(s) and IP payload.
Abstract Data Type: unsigned64
ElementId: 198
Status: current
5.10.4. octetTotalCount
Description:
The total number of octets in incoming packets for this Flow at
the Observation Point since the Metering Process
(re-)initialization for this Observation Point. The number
of octets includes IP header(s) and IP payload.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 85
Status: current
Units: octets
5.10.5. postOctetTotalCount
Description:
The definition of this Information Element is identical to the
definition of Information Element 'octetTotalCount', except that
it reports a potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 171
Status: current
Units: octets
5.10.6. octetTotalSumOfSquares
Description:
The total sum of the squared numbers of octets in incoming packets
for this Flow at the Observation Point since the Metering Process
(re-)initialization for this Observation Point. The number of
octets includes IP header(s) and IP payload.
Abstract Data Type: unsigned64
ElementId: 199
Status: current
Units: octets
Quittek, et al. Standards Track [Page 72]
RFC 5102 IPFIX Information Model January 2008
5.10.7. packetDeltaCount
Description:
The number of incoming packets since the previous report (if any)
for this Flow at the Observation Point.
Abstract Data Type: unsigned64
Data Type Semantics: deltaCounter
ElementId: 2
Status: current
Units: packets
5.10.8. postPacketDeltaCount
Description:
The definition of this Information Element is identical to the
definition of Information Element 'packetDeltaCount', except that
it reports a potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
Abstract Data Type: unsigned64
Data Type Semantics: deltaCounter
ElementId: 24
Status: current
Units: packets
5.10.9. packetTotalCount
Description:
The total number of incoming packets for this Flow at the
Observation Point since the Metering Process (re-)initialization
for this Observation Point.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 86
Status: current
Units: packets
Quittek, et al. Standards Track [Page 73]
RFC 5102 IPFIX Information Model January 2008
5.10.10. postPacketTotalCount
Description:
The definition of this Information Element is identical to the
definition of Information Element 'packetTotalCount', except that
it reports a potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 172
Status: current
Units: packets
5.10.11. droppedOctetDeltaCount
Description:
The number of octets since the previous report (if any) in packets
of this Flow dropped by packet treatment. The number of octets
includes IP header(s) and IP payload.
Abstract Data Type: unsigned64
Data Type Semantics: deltaCounter
ElementId: 132
Status: current
Units: octets
5.10.12. droppedPacketDeltaCount
Description:
The number of packets since the previous report (if any) of this
Flow dropped by packet treatment.
Abstract Data Type: unsigned64
Data Type Semantics: deltaCounter
ElementId: 133
Status: current
Units: packets
5.10.13. droppedOctetTotalCount
Description:
The total number of octets in packets of this Flow dropped by
packet treatment since the Metering Process (re-)initialization
for this Observation Point. The number of octets includes IP
header(s) and IP payload.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 134
Status: current
Units: octets
Quittek, et al. Standards Track [Page 74]
RFC 5102 IPFIX Information Model January 2008
5.10.14. droppedPacketTotalCount
Description:
The number of packets of this Flow dropped by packet treatment
since the Metering Process (re-)initialization for this
Observation Point.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 135
Status: current
Units: packets
5.10.15. postMCastPacketDeltaCount
Description:
The number of outgoing multicast packets since the previous report
(if any) sent for packets of this Flow by a multicast daemon
within the Observation Domain. This property cannot necessarily
be observed at the Observation Point, but may be retrieved by
other means.
Abstract Data Type: unsigned64
Data Type Semantics: deltaCounter
ElementId: 19
Status: current
Units: packets
5.10.16. postMCastOctetDeltaCount
Description:
The number of octets since the previous report (if any) in
outgoing multicast packets sent for packets of this Flow by a
multicast daemon within the Observation Domain. This property
cannot necessarily be observed at the Observation Point, but may
be retrieved by other means. The number of octets includes IP
header(s) and IP payload.
Abstract Data Type: unsigned64
Data Type Semantics: deltaCounter
ElementId: 20
Status: current
Units: octets
Quittek, et al. Standards Track [Page 75]
RFC 5102 IPFIX Information Model January 2008
5.10.17. postMCastPacketTotalCount
Description:
The total number of outgoing multicast packets sent for packets of
this Flow by a multicast daemon within the Observation Domain
since the Metering Process (re-)initialization. This property
cannot necessarily be observed at the Observation Point, but may
be retrieved by other means.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 174
Status: current
Units: packets
5.10.18. postMCastOctetTotalCount
Description:
The total number of octets in outgoing multicast packets sent for
packets of this Flow by a multicast daemon in the Observation
Domain since the Metering Process (re-)initialization. This
property cannot necessarily be observed at the Observation Point,
but may be retrieved by other means. The number of octets
includes IP header(s) and IP payload.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 175
Status: current
Units: octets
5.10.19. tcpSynTotalCount
Description:
The total number of packets of this Flow with TCP "Synchronize
sequence numbers" (SYN) flag set.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 218
Status: current
Units: packets
Reference:
See RFC 793 for the definition of the TCP SYN flag.
Quittek, et al. Standards Track [Page 76]
RFC 5102 IPFIX Information Model January 2008
5.10.20. tcpFinTotalCount
Description:
The total number of packets of this Flow with TCP "No more data
from sender" (FIN) flag set.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 219
Status: current
Units: packets
Reference:
See RFC 793 for the definition of the TCP FIN flag.
5.10.21. tcpRstTotalCount
Description:
The total number of packets of this Flow with TCP "Reset the
connection" (RST) flag set.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 220
Status: current
Units: packets
Reference:
See RFC 793 for the definition of the TCP RST flag.
5.10.22. tcpPshTotalCount
Description:
The total number of packets of this Flow with TCP "Push Function"
(PSH) flag set.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 221
Status: current
Units: packets
Reference:
See RFC 793 for the definition of the TCP PSH flag.
Quittek, et al. Standards Track [Page 77]
RFC 5102 IPFIX Information Model January 2008
5.10.23. tcpAckTotalCount
Description:
The total number of packets of this Flow with TCP "Acknowledgment
field significant" (ACK) flag set.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 222
Status: current
Units: packets
Reference:
See RFC 793 for the definition of the TCP ACK flag.
5.10.24. tcpUrgTotalCount
Description:
The total number of packets of this Flow with TCP "Urgent Pointer
field significant" (URG) flag set.
Abstract Data Type: unsigned64
Data Type Semantics: totalCounter
ElementId: 223
Status: current
Units: packets
Reference:
See RFC 793 for the definition of the TCP URG flag.
5.11. Miscellaneous Flow Properties
Information Elements in this section describe properties of Flows
that are related to Flow start, Flow duration, and Flow termination,
but they are not timestamps as the Information Elements in Section
5.9 are.
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 36 | flowActiveTimeout | 161 | flowDurationMilliseconds |
| 37 | flowIdleTimeout | 162 | flowDurationMicroseconds |
| 136 | flowEndReason | 61 | flowDirection |
+-----+---------------------------+-----+---------------------------+
Quittek, et al. Standards Track [Page 78]
RFC 5102 IPFIX Information Model January 2008
5.11.1. flowActiveTimeout
Description:
The number of seconds after which an active Flow is timed out
anyway, even if there is still a continuous flow of packets.
Abstract Data Type: unsigned16
ElementId: 36
Status: current
Units: seconds
5.11.2. flowIdleTimeout
Description:
A Flow is considered to be timed out if no packets belonging to
the Flow have been observed for the number of seconds specified by
this field.
Abstract Data Type: unsigned16
ElementId: 37
Status: current
Units: seconds
5.11.3. flowEndReason
Description:
The reason for Flow termination. The range of values includes the
following:
0x01: idle timeout
The Flow was terminated because it was considered to be
idle.
0x02: active timeout
The Flow was terminated for reporting purposes while it was
still active, for example, after the maximum lifetime of
unreported Flows was reached.
0x03: end of Flow detected
The Flow was terminated because the Metering Process
detected signals indicating the end of the Flow, for
example, the TCP FIN flag.
0x04: forced end
The Flow was terminated because of some external event, for
example, a shutdown of the Metering Process initiated by a
network management application.
Quittek, et al. Standards Track [Page 79]
RFC 5102 IPFIX Information Model January 2008
0x05: lack of resources
The Flow was terminated because of lack of resources
available to the Metering Process and/or the Exporting
Process.
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 136
Status: current
5.11.4. flowDurationMilliseconds
Description:
The difference in time between the first observed packet of this
Flow and the last observed packet of this Flow.
Abstract Data Type: unsigned32
ElementId: 161
Status: current
Units: milliseconds
5.11.5. flowDurationMicroseconds
Description:
The difference in time between the first observed packet of this
Flow and the last observed packet of this Flow.
Abstract Data Type: unsigned32
ElementId: 162
Status: current
Units: microseconds
5.11.6. flowDirection
Description:
The direction of the Flow observed at the Observation Point.
There are only two values defined.
0x00: ingress flow
0x01: egress flow
Abstract Data Type: unsigned8
Data Type Semantics: identifier
ElementId: 61
Status: current
5.12. Padding
This section contains a single Information Element that can be used
for padding of Flow Records.
Quittek, et al. Standards Track [Page 80]
RFC 5102 IPFIX Information Model January 2008
IPFIX implementations may wish to align Information Elements within
Data Records or to align entire Data Records to 4-octet or 8-octet
boundaries. This can be achieved by including one or more
paddingOctets Information Elements in a Data Record.
+-----+---------------------------+-----+---------------------------+
| ID | Name | ID | Name |
+-----+---------------------------+-----+---------------------------+
| 210 | paddingOctets | | |
+-----+---------------------------+-----+---------------------------+
5.12.1. paddingOctets
Description:
The value of this Information Element is always a sequence of 0x00
values.
Abstract Data Type: octetArray
ElementId: 210
Status: current
6. Extending the Information Model
A key requirement for IPFIX is to allow for extending the set of
Information Elements that are reported. This section defines the
mechanism for extending this set.
Extension can be done by defining new Information Elements. Each new
Information Element MUST be assigned a unique Information Element
identifier as part of its definition. These unique Information
Element identifiers are the connection between the record structure
communicated by the protocol using Templates and a consuming
application. For generally applicable Information Elements, using
IETF and IANA mechanisms to extend the information model is
RECOMMENDED.
Names of new Information Elements SHOULD be chosen according to the
naming conventions given in Section 2.3.
For extensions, the type space defined in Section 3 can be used. If
required, new abstract data types can be added. New abstract data
types MUST be defined in IETF Standards Track documents.
Enterprises may wish to define Information Elements without
registering them with IANA. IPFIX explicitly supports
enterprise-specific Information Elements. Enterprise-specific
Information Elements are described in Sections 2.1 and 4.
Quittek, et al. Standards Track [Page 81]
RFC 5102 IPFIX Information Model January 2008
However, before creating enterprise-specific Information Elements,
the general applicability of such Information Elements should be
considered. IPFIX does not support enterprise-specific abstract data
types.
7. IANA Considerations
7.1. IPFIX Information Elements
This document specifies an initial set of IPFIX Information Elements.
The list of these Information Elements with their identifiers is
given in Section 4. The Internet Assigned Numbers Authority (IANA)
has created a new registry for IPFIX Information Element identifiers
and filled it with the initial list in Section 4.
New assignments for IPFIX Information Elements will be administered
by IANA through Expert Review [RFC2434], i.e., review by one of a
group of experts designated by an IETF Area Director. The group of
experts MUST check the requested Information Element for completeness
and accuracy of the description and for correct naming according to
the naming conventions in Section 2.3. Requests for Information
Elements that duplicate the functionality of existing Information
Elements SHOULD be declined. The smallest available identifier
SHOULD be assigned to a new Information Element.
The specification of new IPFIX Information Elements MUST use the
template specified in Section 2.1 and MUST be published using a
well-established and persistent publication medium. The experts will
initially be drawn from the Working Group Chairs and document editors
of the IPFIX and PSAMP Working Groups.
7.2. MPLS Label Type Identifier
Information Element #46, named mplsTopLabelType, carries MPLS label
types. Values for 5 different types have initially been defined.
For ensuring extensibility of this information, IANA has created a
new registry for MPLS label types and filled it with the initial list
from the description Information Element #46, mplsTopLabelType.
New assignments for MPLS label types will be administered by IANA
through Expert Review [RFC2434], i.e., review by one of a group of
experts designated by an IETF Area Director. The group of experts
must double check the label type definitions with already defined
label types for completeness, accuracy, and redundancy. The
specification of new MPLS label types MUST be published using a
well-established and persistent publication medium.
Quittek, et al. Standards Track [Page 82]
RFC 5102 IPFIX Information Model January 2008
7.3. XML Namespace and Schema
Appendix B defines an XML schema for IPFIX Information Element
definitions. All Information Elements specified in this document are
defined by the XML specification in Appendix A that is a valid XML
record according to the schema in Appendix B. This schema may also
be used for specifying further Information Elements in future
extensions of the IPFIX information model in a machine-readable way.
Appendix B uses URNs to describe an XML namespace and an XML schema
for IPFIX Information Elements conforming to a registry mechanism
described in [RFC3688]. Two URI assignments have been made.
1. Registration for the IPFIX information model namespace
* URI: urn:ietf:params:xml:ns:ipfix-info-15
* Registrant Contact: IETF IPFIX Working Group <ipfix@ietf.org>,
as designated by the IESG <iesg@ietf.org>.
* XML: None. Namespace URIs do not represent an XML.
2. Registration for the IPFIX information model schema
* URI: urn:ietf:params:xml:schema:ipfix-info-15
* Registrant Contact: IETF IPFIX Working Group <ipfix@ietf.org>,
as designated by the IESG <iesg@ietf.org>.
* XML: See Appendix B of this document.
8. Security Considerations
The IPFIX information model itself does not directly introduce
security issues. Rather, it defines a set of attributes that may for
privacy or business issues be considered sensitive information.
For example, exporting values of header fields may make attacks
possible for the receiver of this information, which would otherwise
only be possible for direct observers of the reported Flows along the
data path.
The underlying protocol used to exchange the information described
here must therefore apply appropriate procedures to guarantee the
integrity and confidentiality of the exported information. Such
protocols are defined in separate documents, specifically the IPFIX
protocol document [RFC5101].
This document does not specify any Information Element carrying
keying material. If future extensions will do so, then appropriate
precautions need to be taken for properly protecting such sensitive
information.
Quittek, et al. Standards Track [Page 83]
RFC 5102 IPFIX Information Model January 2008
9. Acknowledgements
The editors thank Paul Callato for creating the initial version of
this document, and Thomas Dietz for developing the XSLT scripts that
generate large portions of the text part of this document from the
XML appendices.
10. References
10.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC5101] Claise, B., "Specification of the IPFIX Protocol for the
Exchange", RFC 5101, January 2008.
10.2. Informative References
[IEEE.754.1985]
Institute of Electrical and Electronics Engineers,
"Standard for Binary Floating-Point Arithmetic", IEEE
Standard 754, August 1985.
[IEEE.802-11.1999]
"Information technology - Telecommunications and
information exchange between systems - Local and
metropolitan area networks - Specific requirements - Part
11: Wireless LAN Medium Access Control (MAC) and Physical
Layer (PHY) specifications", IEEE Standard 802.11, 1999,
<http://standards.ieee.org/getieee802/download/802.11-
1999.pdF>.
[IEEE.802-1Q.2003]
Institute of Electrical and Electronics Engineers, "Local
and Metropolitan Area Networks: Virtual Bridged Local Area
Networks", IEEE Standard 802.1Q, March 2003.
[IEEE.802-3.2002]
"Information technology - Telecommunications and
information exchange between systems - Local and
metropolitan area networks - Specific requirements - Part
3: Carrier sense multiple access with collision detection
(CSMA/CD) access method and physical layer
specifications", IEEE Standard 802.3, September 2002.
Quittek, et al. Standards Track [Page 84]
RFC 5102 IPFIX Information Model January 2008
[ISO.10646-1.1993]
International Organization for Standardization,
"Information Technology - Universal Multiple-octet coded
Character Set (UCS) - Part 1: Architecture and Basic
Multilingual Plane", ISO Standard 10646-1, May 1993.
[ISO.646.1991]
International Organization for Standardization,
"Information technology - ISO 7-bit coded character set
for information interchange", ISO Standard 646, 1991.
[RFC0768] Postel, J., "User Datagram Protocol", STD 6, RFC 768,
August 1980.
[RFC0791] Postel, J., "Internet Protocol", STD 5, RFC 791, September
1981.
[RFC0792] Postel, J., "Internet Control Message Protocol", STD 5,
RFC 792, September 1981.
[RFC0793] Postel, J., "Transmission Control Protocol", STD 7, RFC
793, September 1981.
[RFC1108] Kent, S., "U.S. Department of Defense Security Options for
the Internet Protocol", RFC 1108, November 1991.
[RFC1112] Deering, S., "Host extensions for IP multicasting", STD 5,
RFC 1112, August 1989.
[RFC1191] Mogul, J. and S. Deering, "Path MTU discovery", RFC 1191,
November 1990.
[RFC1323] Jacobson, V., Braden, R., and D. Borman, "TCP Extensions
for High Performance", RFC 1323, May 1992.
[RFC1385] Wang, Z., "EIP: The Extended Internet Protocol", RFC 1385,
November 1992.
[RFC1812] Baker, F., Ed., "Requirements for IP Version 4 Routers",
RFC 1812, June 1995.
[RFC1930] Hawkinson, J. and T. Bates, "Guidelines for creation,
selection, and registration of an Autonomous System (AS)",
BCP 6, RFC 1930, March 1996.
[RFC2113] Katz, D., "IP Router Alert Option", RFC 2113, February
1997.
Quittek, et al. Standards Track [Page 85]
RFC 5102 IPFIX Information Model January 2008
[RFC2434] Narten, T. and H. Alvestrand, "Guidelines for Writing an
IANA Considerations Section in RFCs", BCP 26, RFC 2434,
October 1998.
[RFC2460] Deering, S. and R. Hinden, "Internet Protocol, Version 6
(IPv6) Specification", RFC 2460, December 1998.
[RFC2578] McCloghrie, K., Perkins, D., and J. Schoenwaelder,
"Structure of Management Information Version 2 (SMIv2)",
STD 58, RFC 2578, April 1999.
[RFC2629] Rose, M., "Writing I-Ds and RFCs using XML", RFC 2629,
June 1999.
[RFC2675] Borman, D., Deering, S., and R. Hinden, "IPv6 Jumbograms",
RFC 2675, August 1999.
[RFC2863] McCloghrie, K. and F. Kastenholz, "The Interfaces Group
MIB", RFC 2863, June 2000.
[RFC3031] Rosen, E., Viswanathan, A., and R. Callon, "Multiprotocol
Label Switching Architecture", RFC 3031, January 2001.
[RFC3032] Rosen, E., Tappan, D., Fedorkow, G., Rekhter, Y.,
Farinacci, D., Li, T., and A. Conta, "MPLS Label Stack
Encoding", RFC 3032, January 2001.
[RFC3193] Patel, B., Aboba, B., Dixon, W., Zorn, G., and S. Booth,
"Securing L2TP using IPsec", RFC 3193, November 2001.
[RFC3234] Carpenter, B. and S. Brim, "Middleboxes: Taxonomy and
Issues", RFC 3234, February 2002.
[RFC3260] Grossman, D., "New Terminology and Clarifications for
Diffserv", RFC 3260, April 2002.
[RFC3270] Le Faucheur, F., Wu, L., Davie, B., Davari, S., Vaananen,
P., Krishnan, R., Cheval, P., and J. Heinanen, "Multi-
Protocol Label Switching (MPLS) Support of Differentiated
Services", RFC 3270, May 2002.
[RFC3376] Cain, B., Deering, S., Kouvelas, I., Fenner, B., and A.
Thyagarajan, "Internet Group Management Protocol, Version
3", RFC 3376, October 2002.
[RFC3444] Pras, A. and J. Schoenwaelder, "On the Difference between
Information Models and Data Models", RFC 3444, January
2003.
Quittek, et al. Standards Track [Page 86]
RFC 5102 IPFIX Information Model January 2008
[RFC3688] Mealling, M., "The IETF XML Registry", BCP 81, RFC 3688,
January 2004.
[RFC3954] Claise, B., Ed., "Cisco Systems NetFlow Services Export
Version 9", RFC 3954, October 2004.
[RFC4271] Rekhter, Y., Ed., Li, T., Ed., and S. Hares, Ed., "A
Border Gateway Protocol 4 (BGP-4)", RFC 4271, January
2006.
[RFC4291] Hinden, R. and S. Deering, "IP Version 6 Addressing
Architecture", RFC 4291, February 2006.
[RFC4302] Kent, S., "IP Authentication Header", RFC 4302, December
2005.
[RFC4303] Kent, S., "IP Encapsulating Security Payload (ESP)", RFC
4303, December 2005.
[RFC4364] Rosen, E. and Y. Rekhter, "BGP/MPLS IP Virtual Private
Networks (VPNs)", RFC 4364, February 2006.
[RFC4382] Nadeau, T., Ed., and H. van der Linde, Ed., "MPLS/BGP
Layer 3 Virtual Private Network (VPN) Management
Information Base", RFC 4382, February 2006.
[RFC4443] Conta, A., Deering, S., and M. Gupta, Ed., "Internet
Control Message Protocol (ICMPv6) for the Internet
Protocol Version 6 (IPv6) Specification", RFC 4443, March
2006.
[RFC4960] Stewart, R., Ed., "Stream Control Transmission Protocol",
RFC 4960, September 2007.
[RFC5036] Andersson, L., Ed., Minei, I., Ed., and B. Thomas, Ed.,
"LDP Specification", RFC 5036, October 2007.
Quittek, et al. Standards Track [Page 87]
RFC 5102 IPFIX Information Model January 2008
Appendix A. XML Specification of IPFIX Information Elements
This appendix contains a machine-readable description of the IPFIX
information model coded in XML. Note that this appendix is of
informational nature, while the text in Section 4 (generated from
this appendix) is normative.
Using a machine-readable syntax for the information model enables the
creation of IPFIX-aware tools that can automatically adapt to
extensions to the information model, by simply reading updated
information model specifications.
The wide availability of XML-aware tools and libraries for client
devices is a primary consideration for this choice. In particular,
libraries for parsing XML documents are readily available. Also,
mechanisms such as the Extensible Stylesheet Language (XSL) allow for
transforming a source XML document into other documents. This
document was authored in XML and transformed according to [RFC2629].
It should be noted that the use of XML in Exporters, Collectors, or
other tools is not mandatory for the deployment of IPFIX. In
particular, Exporting Processes do not produce or consume XML as part
of their operation. It is expected that IPFIX Collectors MAY take
advantage of the machine readability of the information model vs.
hard coding their behavior or inventing proprietary means for
accommodating extensions.
<?xml version="1.0" encoding="UTF-8"?>
<fieldDefinitions xmlns="urn:ietf:params:xml:ns:ipfix-info"
xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
xsi:schemaLocation="urn:ietf:params:xml:ns:ipfix-info
ipfix-info.xsd">
<field name="lineCardId" dataType="unsigned32"
group="scope"
dataTypeSemantics="identifier"
elementId="141" applicability="option" status="current">
<description>
<paragraph>
An identifier of a line card that is unique per IPFIX
Device hosting an Observation Point. Typically, this
Information Element is used for limiting the scope
of other Information Elements.
</paragraph>
</description>
</field>
<field name="portId" dataType="unsigned32"
Quittek, et al. Standards Track [Page 88]
RFC 5102 IPFIX Information Model January 2008
group="scope"
dataTypeSemantics="identifier"
elementId="142" applicability="option" status="current">
<description>
<paragraph>
An identifier of a line port that is unique per IPFIX
Device hosting an Observation Point. Typically, this
Information Element is used for limiting the scope
of other Information Elements.
</paragraph>
</description>
</field>
<field name="ingressInterface" dataType="unsigned32"
group="scope"
dataTypeSemantics="identifier"
elementId="10" applicability="all" status="current">
<description>
<paragraph>
The index of the IP interface where packets of this Flow
are being received. The value matches the value of managed
object 'ifIndex' as defined in RFC 2863.
Note that ifIndex values are not assigned statically to an
interface and that the interfaces may be renumbered every
time the device's management system is re-initialized, as
specified in RFC 2863.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 2863 for the definition of the ifIndex object.
</paragraph>
</reference>
</field>
<field name="egressInterface" dataType="unsigned32"
group="scope"
dataTypeSemantics="identifier"
elementId="14" applicability="all" status="current">
<description>
<paragraph>
The index of the IP interface where packets of
this Flow are being sent. The value matches the value of
managed object 'ifIndex' as defined in RFC 2863.
Note that ifIndex values are not assigned statically to an
interface and that the interfaces may be renumbered every
time the device's management system is re-initialized, as
specified in RFC 2863.
Quittek, et al. Standards Track [Page 89]
RFC 5102 IPFIX Information Model January 2008
</paragraph>
</description>
<reference>
<paragraph>
See RFC 2863 for the definition of the ifIndex object.
</paragraph>
</reference>
</field>
<field name="meteringProcessId" dataType="unsigned32"
group="scope"
dataTypeSemantics="identifier"
elementId="143" applicability="option" status="current">
<description>
<paragraph>
An identifier of a Metering Process that is unique per
IPFIX Device. Typically, this Information Element is used
for limiting the scope of other Information Elements.
Note that process identifiers are typically assigned
dynamically.
The Metering Process may be re-started with a different ID.
</paragraph>
</description>
</field>
<field name="exportingProcessId" dataType="unsigned32"
group="scope"
dataTypeSemantics="identifier"
elementId="144" applicability="option" status="current">
<description>
<paragraph>
An identifier of an Exporting Process that is unique per
IPFIX Device. Typically, this Information Element is used
for limiting the scope of other Information Elements.
Note that process identifiers are typically assigned
dynamically. The Exporting Process may be re-started
with a different ID.
</paragraph>
</description>
</field>
<field name="flowId" dataType="unsigned64"
group="scope"
dataTypeSemantics="identifier"
elementId="148" applicability="option" status="current">
<description>
<paragraph>
An identifier of a Flow that is unique within an Observation
Quittek, et al. Standards Track [Page 90]
RFC 5102 IPFIX Information Model January 2008
Domain. This Information Element can be used to distinguish
between different Flows if Flow Keys such as IP addresses and
port numbers are not reported or are reported in separate
records.
</paragraph>
</description>
</field>
<field name="templateId" dataType="unsigned16"
group="scope"
dataTypeSemantics="identifier"
elementId="145" applicability="option" status="current">
<description>
<paragraph>
An identifier of a Template that is locally unique within a
combination of a Transport session and an Observation Domain.
</paragraph>
<paragraph>
Template IDs 0-255 are reserved for Template Sets, Options
Template Sets, and other reserved Sets yet to be created.
Template IDs of Data Sets are numbered from 256 to 65535.
</paragraph>
<paragraph>
Typically, this Information Element is used for limiting
the scope of other Information Elements.
Note that after a re-start of the Exporting Process Template
identifiers may be re-assigned.
</paragraph>
</description>
</field>
<field name="observationDomainId" dataType="unsigned32"
group="scope"
dataTypeSemantics="identifier"
elementId="149" applicability="option" status="current">
<description>
<paragraph>
An identifier of an Observation Domain that is locally
unique to an Exporting Process. The Exporting Process uses
the Observation Domain ID to uniquely identify to the
Collecting Process the Observation Domain where Flows
were metered. It is RECOMMENDED that this identifier is
also unique per IPFIX Device.
</paragraph>
<paragraph>
A value of 0 indicates that no specific Observation Domain
is identified by this Information Element.
</paragraph>
Quittek, et al. Standards Track [Page 91]
RFC 5102 IPFIX Information Model January 2008
<paragraph>
Typically, this Information Element is used for limiting
the scope of other Information Elements.
</paragraph>
</description>
</field>
<field name="observationPointId" dataType="unsigned32"
group="scope"
dataTypeSemantics="identifier"
elementId="138" applicability="option" status="current">
<description>
<paragraph>
An identifier of an Observation Point that is unique per
Observation Domain. It is RECOMMENDED that this identifier is
also unique per IPFIX Device. Typically, this Information
Element is used for limiting the scope of other Information
Elements.
</paragraph>
</description>
</field>
<field name="commonPropertiesId" dataType="unsigned64"
group="scope"
dataTypeSemantics="identifier"
elementId="137" applicability="option" status="current">
<description>
<paragraph>
An identifier of a set of common properties that is
unique per Observation Domain and Transport Session.
Typically, this Information Element is used to link to
information reported in separate Data Records.
</paragraph>
</description>
</field>
<field name="exporterIPv4Address" dataType="ipv4Address"
dataTypeSemantics="identifier"
group="config"
elementId="130" applicability="all" status="current">
<description>
<paragraph>
The IPv4 address used by the Exporting Process. This is used
by the Collector to identify the Exporter in cases where the
identity of the Exporter may have been obscured by the use of
a proxy.
</paragraph>
</description>
</field>
Quittek, et al. Standards Track [Page 92]
RFC 5102 IPFIX Information Model January 2008
<field name="exporterIPv6Address" dataType="ipv6Address"
dataTypeSemantics="identifier"
group="config"
elementId="131" applicability="all" status="current">
<description>
<paragraph>
The IPv6 address used by the Exporting Process. This is used
by the Collector to identify the Exporter in cases where the
identity of the Exporter may have been obscured by the use of
a proxy.
</paragraph>
</description>
</field>
<field name="exporterTransportPort" dataType="unsigned16"
group="config"
dataTypeSemantics="identifier"
elementId="217" applicability="all" status="current">
<description>
<paragraph>
The source port identifier from which the Exporting
Process sends Flow information. For the transport protocols
UDP, TCP, and SCTP, this is the source port number.
This field MAY also be used for future transport protocols
that have 16-bit source port identifiers. This field may
be useful for distinguishing multiple Exporting Processes
that use the same IP address.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 768 for the definition of the UDP
source port field.
See RFC 793 for the definition of the TCP
source port field.
See RFC 4960 for the definition of SCTP.
</paragraph>
<paragraph>
Additional information on defined UDP and TCP port numbers can
be found at http://www.iana.org/assignments/port-numbers.
</paragraph>
</reference>
</field>
<field name="collectorIPv4Address" dataType="ipv4Address"
dataTypeSemantics="identifier"
group="config"
elementId="211" applicability="all" status="current">
Quittek, et al. Standards Track [Page 93]
RFC 5102 IPFIX Information Model January 2008
<description>
<paragraph>
An IPv4 address to which the Exporting Process sends Flow
information.
</paragraph>
</description>
</field>
<field name="collectorIPv6Address" dataType="ipv6Address"
dataTypeSemantics="identifier"
group="config"
elementId="212" applicability="all" status="current">
<description>
<paragraph>
An IPv6 address to which the Exporting Process sends Flow
information.
</paragraph>
</description>
</field>
<field name="exportInterface" dataType="unsigned32"
group="config"
dataTypeSemantics="identifier"
elementId="213" applicability="all" status="current">
<description>
<paragraph>
The index of the interface from which IPFIX Messages sent
by the Exporting Process to a Collector leave the IPFIX
Device. The value matches the value of
managed object 'ifIndex' as defined in RFC 2863.
Note that ifIndex values are not assigned statically to an
interface and that the interfaces may be renumbered every
time the device's management system is re-initialized, as
specified in RFC 2863.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 2863 for the definition of the ifIndex object.
</paragraph>
</reference>
</field>
<field name="exportProtocolVersion" dataType="unsigned8"
dataTypeSemantics="identifier"
group="config"
elementId="214" applicability="all" status="current">
<description>
Quittek, et al. Standards Track [Page 94]
RFC 5102 IPFIX Information Model January 2008
<paragraph>
The protocol version used by the Exporting Process for
sending Flow information. The protocol version is given
by the value of the Version Number field in the Message
Header.
</paragraph>
<paragraph>
The protocol version is 10 for IPFIX and 9 for NetFlow
version 9.
A value of 0 indicates that no export protocol is in use.
</paragraph>
</description>
<reference>
<paragraph>
See the IPFIX protocol specification [RFC5101] for the
definition of the IPFIX Message Header.
</paragraph>
<paragraph>
See RFC 3954 for the definition of the NetFlow
version 9 message header.
</paragraph>
</reference>
</field>
<field name="exportTransportProtocol" dataType="unsigned8"
group="config"
dataTypeSemantics="identifier"
elementId="215" applicability="all" status="current">
<description>
<paragraph>
The value of the protocol number used by the Exporting Process
for sending Flow information.
The protocol number identifies the IP packet payload type.
Protocol numbers are defined in the IANA Protocol Numbers
registry.
</paragraph>
<paragraph>
In Internet Protocol version 4 (IPv4), this is carried in the
Protocol field. In Internet Protocol version 6 (IPv6), this
is carried in the Next Header field in the last extension
header of the packet.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of the IPv4
protocol field.
Quittek, et al. Standards Track [Page 95]
RFC 5102 IPFIX Information Model January 2008
See RFC 2460 for the specification of the IPv6
protocol field.
See the list of protocol numbers assigned by IANA at
http://www.iana.org/assignments/protocol-numbers.
</paragraph>
</reference>
</field>
<field name="collectorTransportPort" dataType="unsigned16"
group="config"
dataTypeSemantics="identifier"
elementId="216" applicability="all" status="current">
<description>
<paragraph>
The destination port identifier to which the Exporting
Process sends Flow information. For the transport protocols
UDP, TCP, and SCTP, this is the destination port number.
This field MAY also be used for future transport protocols
that have 16-bit source port identifiers.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 768 for the definition of the UDP
destination port field.
See RFC 793 for the definition of the TCP
destination port field.
See RFC 4960 for the definition of SCTP.
</paragraph>
<paragraph>
Additional information on defined UDP and TCP port numbers can
be found at http://www.iana.org/assignments/port-numbers.
</paragraph>
</reference>
</field>
<field name="flowKeyIndicator" dataType="unsigned64"
dataTypeSemantics="flags"
group="config"
elementId="173" applicability="all" status="current">
<description>
<paragraph>
This set of bit fields is used for marking the Information
Elements of a Data Record that serve as Flow Key. Each bit
represents an Information Element in the Data Record with
the n-th bit representing the n-th Information Element.
A bit set to value 1 indicates that the corresponding
Information Element is a Flow Key of the reported Flow.
Quittek, et al. Standards Track [Page 96]
RFC 5102 IPFIX Information Model January 2008
A bit set to value 0 indicates that this is not the case.
</paragraph>
<paragraph>
If the Data Record contains more than 64 Information Elements,
the corresponding Template SHOULD be designed such that all
Flow Keys are among the first 64 Information Elements, because
the flowKeyIndicator only contains 64 bits. If the Data Record
contains less than 64 Information Elements, then the bits in
the flowKeyIndicator for which no corresponding Information
Element exists MUST have the value 0.
</paragraph>
</description>
</field>
<field name="exportedMessageTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="processCounter"
elementId="41" applicability="data" status="current">
<description>
<paragraph>
The total number of IPFIX Messages that the Exporting Process
has sent since the Exporting Process (re-)initialization to
a particular Collecting Process.
The reported number excludes the IPFIX Message that carries
the counter value.
If this Information Element is sent to a particular
Collecting Process, then by default it specifies the number
of IPFIX Messages sent to this Collecting Process.
</paragraph>
</description>
<units>messages</units>
</field>
<field name="exportedOctetTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="processCounter"
elementId="40" applicability="data" status="current">
<description>
<paragraph>
The total number of octets that the Exporting Process
has sent since the Exporting Process (re-)initialization
to a particular Collecting Process.
The value of this Information Element is calculated by
summing up the IPFIX Message Header length values of all
IPFIX Messages that were successfully sent to the Collecting
Process. The reported number excludes octets in the IPFIX
Message that carries the counter value.
If this Information Element is sent to a particular
Quittek, et al. Standards Track [Page 97]
RFC 5102 IPFIX Information Model January 2008
Collecting Process, then by default it specifies the number
of octets sent to this Collecting Process.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="exportedFlowRecordTotalCount" dataType="unsigned64"
group="processCounter"
dataTypeSemantics="totalCounter"
elementId="42" applicability="data" status="current">
<description>
<paragraph>
The total number of Flow Records that the Exporting
Process has sent as Data Records since the Exporting
Process (re-)initialization to a particular Collecting
Process. The reported number excludes Flow Records in
the IPFIX Message that carries the counter value.
If this Information Element is sent to a particular
Collecting Process, then by default it specifies the number
of Flow Records sent to this process.
</paragraph>
</description>
<units>flows</units>
</field>
<field name="observedFlowTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="processCounter"
elementId="163" applicability="data" status="current">
<description>
<paragraph>
The total number of Flows observed in the Observation Domain
since the Metering Process (re-)initialization for this
Observation Point.
</paragraph>
</description>
<units>flows</units>
</field>
<field name="ignoredPacketTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="processCounter"
elementId="164" applicability="data" status="current">
<description>
<paragraph>
The total number of observed IP packets that the
Metering Process did not process since the
Quittek, et al. Standards Track [Page 98]
RFC 5102 IPFIX Information Model January 2008
(re-)initialization of the Metering Process.
</paragraph>
</description>
<units>packets</units>
</field>
<field name="ignoredOctetTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="processCounter"
elementId="165" applicability="data" status="current">
<description>
<paragraph>
The total number of octets in observed IP packets
(including the IP header) that the Metering Process
did not process since the (re-)initialization of the
Metering Process.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="notSentFlowTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="processCounter"
elementId="166" applicability="data" status="current">
<description>
<paragraph>
The total number of Flow Records that were generated by the
Metering Process and dropped by the Metering Process or
by the Exporting Process instead of being sent to the
Collecting Process. There are several potential reasons for
this including resource shortage and special Flow export
policies.
</paragraph>
</description>
<units>flows</units>
</field>
<field name="notSentPacketTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="processCounter"
elementId="167" applicability="data" status="current">
<description>
<paragraph>
The total number of packets in Flow Records that were
generated by the Metering Process and dropped
by the Metering Process or by the Exporting Process
instead of being sent to the Collecting Process.
Quittek, et al. Standards Track [Page 99]
RFC 5102 IPFIX Information Model January 2008
There are several potential reasons for this including
resource shortage and special Flow export policies.
</paragraph>
</description>
<units>packets</units>
</field>
<field name="notSentOctetTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="processCounter"
elementId="168" applicability="data" status="current">
<description>
<paragraph>
The total number of octets in packets in Flow Records
that were generated by the Metering Process and
dropped by the Metering Process or by the Exporting
Process instead of being sent to the Collecting Process.
There are several potential reasons for this including
resource shortage and special Flow export policies.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="ipVersion" dataType="unsigned8"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="60" applicability="all" status="current">
<description>
<paragraph>
The IP version field in the IP packet header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the definition of the version field
in the IPv4 packet header.
See RFC 2460 for the definition of the version field
in the IPv6 packet header.
Additional information on defined version numbers
can be found at
http://www.iana.org/assignments/version-numbers.
</paragraph>
</reference>
</field>
<field name="sourceIPv4Address" dataType="ipv4Address"
group="ipHeader"
Quittek, et al. Standards Track [Page 100]
RFC 5102 IPFIX Information Model January 2008
dataTypeSemantics="identifier"
elementId="8" applicability="all" status="current">
<description>
<paragraph>
The IPv4 source address in the IP packet header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the definition of the IPv4 source
address field.
</paragraph>
</reference>
</field>
<field name="sourceIPv6Address" dataType="ipv6Address"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="27" applicability="all" status="current">
<description>
<paragraph>
The IPv6 source address in the IP packet header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 2460 for the definition of the
Source Address field in the IPv6 header.
</paragraph>
</reference>
</field>
<field name="sourceIPv4PrefixLength" dataType="unsigned8"
group="ipHeader"
elementId="9" applicability="option" status="current">
<description>
<paragraph>
The number of contiguous bits that are relevant in the
sourceIPv4Prefix Information Element.
</paragraph>
</description>
<units>bits</units>
<range>0-32</range>
</field>
<field name="sourceIPv6PrefixLength" dataType="unsigned8"
group="ipHeader"
elementId="29" applicability="option" status="current">
Quittek, et al. Standards Track [Page 101]
RFC 5102 IPFIX Information Model January 2008
<description>
<paragraph>
The number of contiguous bits that are relevant in the
sourceIPv6Prefix Information Element.
</paragraph>
</description>
<units>bits</units>
<range>0-128</range>
</field>
<field name="sourceIPv4Prefix" dataType="ipv4Address"
group="ipHeader"
elementId="44" applicability="data" status="current">
<description>
<paragraph>
IPv4 source address prefix.
</paragraph>
</description>
</field>
<field name="sourceIPv6Prefix" dataType="ipv6Address"
group="ipHeader"
elementId="170" applicability="data" status="current">
<description>
<paragraph>
IPv6 source address prefix.
</paragraph>
</description>
</field>
<field name="destinationIPv4Address" dataType="ipv4Address"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="12" applicability="all" status="current">
<description>
<paragraph>
The IPv4 destination address in the IP packet header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the definition of the IPv4
destination address field.
</paragraph>
</reference>
</field>
<field name="destinationIPv6Address" dataType="ipv6Address"
Quittek, et al. Standards Track [Page 102]
RFC 5102 IPFIX Information Model January 2008
group="ipHeader"
dataTypeSemantics="identifier"
elementId="28" applicability="all" status="current">
<description>
<paragraph>
The IPv6 destination address in the IP packet header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 2460 for the definition of the
Destination Address field in the IPv6 header.
</paragraph>
</reference>
</field>
<field name="destinationIPv4PrefixLength" dataType="unsigned8"
group="ipHeader"
elementId="13" applicability="option" status="current">
<description>
<paragraph>
The number of contiguous bits that are relevant in the
destinationIPv4Prefix Information Element.
</paragraph>
</description>
<units>bits</units>
<range>0-32</range>
</field>
<field name="destinationIPv6PrefixLength" dataType="unsigned8"
group="ipHeader"
elementId="30" applicability="option" status="current">
<description>
<paragraph>
The number of contiguous bits that are relevant in the
destinationIPv6Prefix Information Element.
</paragraph>
</description>
<units>bits</units>
<range>0-128</range>
</field>
<field name="destinationIPv4Prefix" dataType="ipv4Address"
group="ipHeader"
elementId="45" applicability="data" status="current">
<description>
<paragraph> IPv4 destination address prefix. </paragraph>
</description>
Quittek, et al. Standards Track [Page 103]
RFC 5102 IPFIX Information Model January 2008
</field>
<field name="destinationIPv6Prefix" dataType="ipv6Address"
group="ipHeader"
elementId="169" applicability="data" status="current">
<description>
<paragraph> IPv6 destination address prefix. </paragraph>
</description>
</field>
<field name="ipTTL" dataType="unsigned8"
group="ipHeader"
elementId="192" applicability="all" status="current">
<description>
<paragraph>
For IPv4, the value of the Information Element matches
the value of the Time to Live (TTL) field in the IPv4 packet
header. For IPv6, the value of the Information Element
matches the value of the Hop Limit field in the IPv6
packet header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the definition of the IPv4
Time to Live field.
See RFC 2460 for the definition of the IPv6
Hop Limit field.
</paragraph>
</reference>
<units>hops</units>
</field>
<field name="protocolIdentifier" dataType="unsigned8"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="4" applicability="all" status="current">
<description>
<paragraph>
The value of the protocol number in the IP packet header.
The protocol number identifies the IP packet payload type.
Protocol numbers are defined in the IANA Protocol Numbers
registry.
</paragraph>
<paragraph>
In Internet Protocol version 4 (IPv4), this is carried in the
Protocol field. In Internet Protocol version 6 (IPv6), this
Quittek, et al. Standards Track [Page 104]
RFC 5102 IPFIX Information Model January 2008
is carried in the Next Header field in the last extension
header of the packet.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of the IPv4
protocol field.
See RFC 2460 for the specification of the IPv6
protocol field.
See the list of protocol numbers assigned by IANA at
http://www.iana.org/assignments/protocol-numbers.
</paragraph>
</reference>
</field>
<field name="nextHeaderIPv6" dataType="unsigned8"
group="ipHeader"
elementId="193" applicability="all" status="current">
<description>
<paragraph>
The value of the Next Header field of the IPv6 header.
The value identifies the type of the following IPv6
extension header or of the following IP payload.
Valid values are defined in the IANA
Protocol Numbers registry.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 2460 for the definition of the IPv6
Next Header field.
See the list of protocol numbers assigned by IANA at
http://www.iana.org/assignments/protocol-numbers.
</paragraph>
</reference>
</field>
<field name="ipDiffServCodePoint" dataType="unsigned8"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="195" applicability="all" status="current">
<description>
<paragraph>
The value of a Differentiated Services Code Point (DSCP)
encoded in the Differentiated Services field. The
Differentiated Services field spans the most significant
6 bits of the IPv4 TOS field or the IPv6 Traffic Class
Quittek, et al. Standards Track [Page 105]
RFC 5102 IPFIX Information Model January 2008
field, respectively.
</paragraph>
<paragraph>
This Information Element encodes only the 6 bits of the
Differentiated Services field. Therefore, its value may
range from 0 to 63.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3260 for the definition of the
Differentiated Services field.
See RFC 1812 (Section 5.3.2) and RFC 791 for the definition
of the IPv4 TOS field. See RFC 2460 for the definition of
the IPv6 Traffic Class field.
</paragraph>
</reference>
<range>0-63</range>
</field>
<field name="ipPrecedence" dataType="unsigned8"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="196" applicability="all" status="current">
<description>
<paragraph>
The value of the IP Precedence. The IP Precedence value
is encoded in the first 3 bits of the IPv4 TOS field
or the IPv6 Traffic Class field, respectively.
</paragraph>
<paragraph>
This Information Element encodes only these 3 bits.
Therefore, its value may range from 0 to 7.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 1812 (Section 5.3.3) and RFC 791
for the definition of the IP Precedence.
See RFC 1812 (Section 5.3.2) and RFC 791
for the definition of the IPv4 TOS field.
See RFC 2460 for the definition of the IPv6
Traffic Class field.
</paragraph>
</reference>
<range>0-7</range>
</field>
Quittek, et al. Standards Track [Page 106]
RFC 5102 IPFIX Information Model January 2008
<field name="ipClassOfService" dataType="unsigned8"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="5" applicability="all" status="current">
<description>
<paragraph>
For IPv4 packets, this is the value of the TOS field in
the IPv4 packet header. For IPv6 packets, this is the
value of the Traffic Class field in the IPv6 packet header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 1812 (Section 5.3.2) and RFC 791
for the definition of the IPv4 TOS field.
See RFC 2460 for the definition of the IPv6
Traffic Class field.
</paragraph>
</reference>
</field>
<field name="postIpClassOfService" dataType="unsigned8"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="55" applicability="all" status="current">
<description>
<paragraph>
The definition of this Information Element is identical
to the definition of Information Element
'ipClassOfService', except that it reports a
potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the definition of the IPv4
TOS field.
See RFC 2460 for the definition of the IPv6
Traffic Class field.
See RFC 3234 for the definition of middleboxes.
</paragraph>
</reference>
</field>
<field name="flowLabelIPv6" dataType="unsigned32"
group="ipHeader"
dataTypeSemantics="identifier"
Quittek, et al. Standards Track [Page 107]
RFC 5102 IPFIX Information Model January 2008
elementId="31" applicability="all" status="current">
<description>
<paragraph>
The value of the IPv6 Flow Label field in the IP packet header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 2460 for the definition of the
Flow Label field in the IPv6 packet header.
</paragraph>
</reference>
</field>
<field name="isMulticast" dataType="unsigned8"
group="ipHeader"
dataTypeSemantics="flags"
elementId="206" applicability="data" status="current">
<description>
<paragraph>
If the IP destination address is not a reserved multicast
address, then the value of all bits of the octet (including
the reserved ones) is zero.
</paragraph>
<paragraph>
The first bit of this octet is set to 1 if the Version
field of the IP header has the value 4 and if the
Destination Address field contains a reserved multicast
address in the range from 224.0.0.0 to 239.255.255.255.
Otherwise, this bit is set to 0.
</paragraph>
<paragraph>
The second and third bits of this octet are reserved for
future use.
</paragraph>
<paragraph>
The remaining bits of the octet are only set to values
other than zero if the IP Destination Address is a
reserved IPv6 multicast address. Then the fourth bit
of the octet is set to the value of the T flag in the
IPv6 multicast address and the remaining four bits are
set to the value of the scope field in the IPv6
multicast address.
</paragraph>
<artwork>
0 1 2 3 4 5 6 7
+------+------+------+------+------+------+------+------+
| MCv4 | RES. | RES. | T | IPv6 multicast scope |
Quittek, et al. Standards Track [Page 108]
RFC 5102 IPFIX Information Model January 2008
+------+------+------+------+------+------+------+------+
Bit 0: set to 1 if IPv4 multicast
Bits 1-2: reserved for future use
Bit 4: set to value of T flag, if IPv6 multicast
Bits 4-7: set to value of multicast scope if IPv6 multicast
</artwork>
</description>
<reference>
<paragraph>
See RFC 1112 for the specification of reserved
IPv4 multicast addresses.
See RFC 4291 for the specification of reserved
IPv6 multicast addresses and the definition of the T flag
and the IPv6 multicast scope.
</paragraph>
</reference>
</field>
<field name="fragmentIdentification" dataType="unsigned32"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="54" applicability="data" status="current">
<description>
<paragraph>
The value of the Identification field
in the IPv4 packet header or in the IPv6 Fragment header,
respectively. The value is 0 for IPv6 if there is
no fragment header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the definition of the IPv4
Identification field.
See RFC 2460 for the definition of the
Identification field in the IPv6 Fragment header.
</paragraph>
</reference>
</field>
<field name="fragmentOffset" dataType="unsigned16"
group="ipHeader"
dataTypeSemantics="identifier"
elementId="88" applicability="all" status="current">
<description>
<paragraph>
The value of the IP fragment offset field in the
Quittek, et al. Standards Track [Page 109]
RFC 5102 IPFIX Information Model January 2008
IPv4 packet header or the IPv6 Fragment header,
respectively. The value is 0 for IPv6 if there is
no fragment header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of the
fragment offset in the IPv4 header.
See RFC 2460 for the specification of the
fragment offset in the IPv6 Fragment header.
</paragraph>
</reference>
</field>
<field name="fragmentFlags" dataType="unsigned8"
group="ipHeader"
dataTypeSemantics="flags"
elementId="197" applicability="all" status="current">
<description>
<paragraph>
Fragmentation properties indicated by flags in the IPv4
packet header or the IPv6 Fragment header, respectively.
</paragraph>
<artwork>
Bit 0: (RS) Reserved.
The value of this bit MUST be 0 until specified
otherwise.
Bit 1: (DF) 0 = May Fragment, 1 = Don't Fragment.
Corresponds to the value of the DF flag in the
IPv4 header. Will always be 0 for IPv6 unless
a "don't fragment" feature is introduced to IPv6.
Bit 2: (MF) 0 = Last Fragment, 1 = More Fragments.
Corresponds to the MF flag in the IPv4 header
or to the M flag in the IPv6 Fragment header,
respectively. The value is 0 for IPv6 if there
is no fragment header.
Bits 3-7: (DC) Don't Care.
The values of these bits are irrelevant.
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| R | D | M | D | D | D | D | D |
| S | F | F | C | C | C | C | C |
+---+---+---+---+---+---+---+---+
</artwork>
</description>
Quittek, et al. Standards Track [Page 110]
RFC 5102 IPFIX Information Model January 2008
<reference>
<paragraph>
See RFC 791 for the specification of the IPv4
fragment flags.
See RFC 2460 for the specification of the IPv6
Fragment header.
</paragraph>
</reference>
</field>
<field name="ipHeaderLength" dataType="unsigned8"
group="ipHeader"
elementId="189" applicability="all" status="current">
<description>
<paragraph>
The length of the IP header. For IPv6, the value of this
Information Element is 40.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of the
IPv4 header.
See RFC 2460 for the specification of the
IPv6 header.
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="ipv4IHL" dataType="unsigned8"
group="ipHeader"
elementId="207" applicability="all" status="current">
<description>
<paragraph>
The value of the Internet Header Length (IHL) field in
the IPv4 header. It specifies the length of the header
in units of 4 octets. Please note that its unit is
different from most of the other Information Elements
reporting length values.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of the
IPv4 header.
</paragraph>
</reference>
Quittek, et al. Standards Track [Page 111]
RFC 5102 IPFIX Information Model January 2008
<units>4 octets</units>
</field>
<field name="totalLengthIPv4" dataType="unsigned16"
group="ipHeader"
elementId="190" applicability="all" status="current">
<description>
<paragraph>
The total length of the IPv4 packet.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of the
IPv4 total length.
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="ipTotalLength" dataType="unsigned64"
group="ipHeader"
elementId="224" applicability="all" status="current">
<description>
<paragraph>
The total length of the IP packet.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of the
IPv4 total length.
See RFC 2460 for the specification of the
IPv6 payload length.
See RFC 2675 for the specification of the
IPv6 jumbo payload length.
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="payloadLengthIPv6" dataType="unsigned16"
group="ipHeader"
elementId="191" applicability="all" status="current">
<description>
<paragraph>
This Information Element reports the value of the Payload
Length field in the IPv6 header. Note that IPv6 extension
Quittek, et al. Standards Track [Page 112]
RFC 5102 IPFIX Information Model January 2008
headers belong to the payload. Also note that in case of a
jumbo payload option the value of the Payload Length field in
the IPv6 header is zero and so will be the value reported
by this Information Element.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 2460 for the specification of the
IPv6 payload length.
See RFC 2675 for the specification of the
IPv6 jumbo payload option.
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="sourceTransportPort" dataType="unsigned16"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="7" applicability="all" status="current">
<description>
<paragraph>
The source port identifier in the transport header.
For the transport protocols UDP, TCP, and SCTP, this is the
source port number given in the respective header. This
field MAY also be used for future transport protocols that
have 16-bit source port identifiers.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 768 for the definition of the UDP
source port field.
See RFC 793 for the definition of the TCP
source port field.
See RFC 4960 for the definition of SCTP.
</paragraph>
<paragraph>
Additional information on defined UDP and TCP port numbers can
be found at http://www.iana.org/assignments/port-numbers.
</paragraph>
</reference>
</field>
<field name="destinationTransportPort" dataType="unsigned16"
group="transportHeader"
dataTypeSemantics="identifier"
Quittek, et al. Standards Track [Page 113]
RFC 5102 IPFIX Information Model January 2008
elementId="11" applicability="all" status="current">
<description>
<paragraph>
The destination port identifier in the transport header.
For the transport protocols UDP, TCP, and SCTP, this is the
destination port number given in the respective header.
This field MAY also be used for future transport protocols
that have 16-bit destination port identifiers.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 768 for the definition of the UDP
destination port field.
See RFC 793 for the definition of the TCP
destination port field.
See RFC 4960 for the definition of SCTP.
</paragraph>
<paragraph>
Additional information on defined UDP and TCP port numbers can
be found at http://www.iana.org/assignments/port-numbers.
</paragraph>
</reference>
</field>
<field name="udpSourcePort" dataType="unsigned16"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="180" applicability="all" status="current">
<description>
<paragraph>
The source port identifier in the UDP header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 768 for the definition of the
UDP source port field.
Additional information on defined UDP port numbers can
be found at http://www.iana.org/assignments/port-numbers.
</paragraph>
</reference>
</field>
<field name="udpDestinationPort" dataType="unsigned16"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="181" applicability="all" status="current">
Quittek, et al. Standards Track [Page 114]
RFC 5102 IPFIX Information Model January 2008
<description>
<paragraph>
The destination port identifier in the UDP header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 768 for the definition of the
UDP destination port field.
Additional information on defined UDP port numbers can
be found at http://www.iana.org/assignments/port-numbers.
</paragraph>
</reference>
</field>
<field name="udpMessageLength" dataType="unsigned16"
group="transportHeader"
elementId="205" applicability="all" status="current">
<description>
<paragraph>
The value of the Length field in the UDP header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 768 for the specification of the
UDP header.
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="tcpSourcePort" dataType="unsigned16"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="182" applicability="all" status="current">
<description>
<paragraph>
The source port identifier in the TCP header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP
source port field.
Additional information on defined TCP port numbers can
be found at http://www.iana.org/assignments/port-numbers.
</paragraph>
Quittek, et al. Standards Track [Page 115]
RFC 5102 IPFIX Information Model January 2008
</reference>
</field>
<field name="tcpDestinationPort" dataType="unsigned16"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="183" applicability="all" status="current">
<description>
<paragraph>
The destination port identifier in the TCP header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP
source port field.
Additional information on defined TCP port numbers can
be found at http://www.iana.org/assignments/port-numbers.
</paragraph>
</reference>
</field>
<field name="tcpSequenceNumber" dataType="unsigned32"
group="transportHeader"
elementId="184" applicability="all" status="current">
<description>
<paragraph>
The sequence number in the TCP header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP
sequence number.
</paragraph>
</reference>
</field>
<field name="tcpAcknowledgementNumber" dataType="unsigned32"
group="transportHeader"
elementId="185" applicability="all" status="current">
<description>
<paragraph>
The acknowledgement number in the TCP header.
</paragraph>
</description>
<reference>
<paragraph>
Quittek, et al. Standards Track [Page 116]
RFC 5102 IPFIX Information Model January 2008
See RFC 793 for the definition of the TCP
acknowledgement number.
</paragraph>
</reference>
</field>
<field name="tcpWindowSize" dataType="unsigned16"
group="transportHeader"
elementId="186" applicability="all" status="current">
<description>
<paragraph>
The window field in the TCP header.
If the TCP window scale is supported,
then TCP window scale must be known
to fully interpret the value of this information.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP window field.
See RFC 1323 for the definition of the TCP window scale.
</paragraph>
</reference>
</field>
<field name="tcpWindowScale" dataType="unsigned16"
group="transportHeader"
elementId="238" applicability="all" status="current">
<description>
<paragraph>
The scale of the window field in the TCP header.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 1323 for the definition of the TCP window scale.
</paragraph>
</reference>
</field>
<field name="tcpUrgentPointer" dataType="unsigned16"
group="transportHeader"
elementId="187" applicability="all" status="current">
<description>
<paragraph>
The urgent pointer in the TCP header.
</paragraph>
</description>
Quittek, et al. Standards Track [Page 117]
RFC 5102 IPFIX Information Model January 2008
<reference>
<paragraph>
See RFC 793 for the definition of the TCP
urgent pointer.
</paragraph>
</reference>
</field>
<field name="tcpHeaderLength" dataType="unsigned8"
group="transportHeader"
elementId="188" applicability="all" status="current">
<description>
<paragraph>
The length of the TCP header. Note that the value of this
Information Element is different from the value of the Data
Offset field in the TCP header. The Data Offset field
indicates the length of the TCP header in units of 4 octets.
This Information Elements specifies the length of the TCP
header in units of octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the
TCP header.
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="icmpTypeCodeIPv4" dataType="unsigned16"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="32" applicability="all" status="current">
<description>
<paragraph>
Type and Code of the IPv4 ICMP message. The combination of
both values is reported as (ICMP type * 256) + ICMP code.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 792 for the definition of the IPv4 ICMP
type and code fields.
</paragraph>
</reference>
</field>
Quittek, et al. Standards Track [Page 118]
RFC 5102 IPFIX Information Model January 2008
<field name="icmpTypeIPv4" dataType="unsigned8"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="176" applicability="all" status="current">
<description>
<paragraph>
Type of the IPv4 ICMP message.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 792 for the definition of the IPv4 ICMP
type field.
</paragraph>
</reference>
</field>
<field name="icmpCodeIPv4" dataType="unsigned8"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="177" applicability="all" status="current">
<description>
<paragraph>
Code of the IPv4 ICMP message.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 792 for the definition of the IPv4
ICMP code field.
</paragraph>
</reference>
</field>
<field name="icmpTypeCodeIPv6" dataType="unsigned16"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="139" applicability="all" status="current">
<description>
<paragraph>
Type and Code of the IPv6 ICMP message. The combination of
both values is reported as (ICMP type * 256) + ICMP code.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4443 for the definition of the IPv6
ICMP type and code fields.
Quittek, et al. Standards Track [Page 119]
RFC 5102 IPFIX Information Model January 2008
</paragraph>
</reference>
</field>
<field name="icmpTypeIPv6" dataType="unsigned8"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="178" applicability="all" status="current">
<description>
<paragraph>
Type of the IPv6 ICMP message.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4443 for the definition of the IPv6
ICMP type field.
</paragraph>
</reference>
</field>
<field name="icmpCodeIPv6" dataType="unsigned8"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="179" applicability="all" status="current">
<description>
<paragraph>
Code of the IPv6 ICMP message.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4443 for the definition of the IPv6
ICMP code field.
</paragraph>
</reference>
</field>
<field name="igmpType" dataType="unsigned8"
group="transportHeader"
dataTypeSemantics="identifier"
elementId="33" applicability="all" status="current">
<description>
<paragraph>
The type field of the IGMP message.
</paragraph>
</description>
<reference>
Quittek, et al. Standards Track [Page 120]
RFC 5102 IPFIX Information Model January 2008
<paragraph>
See RFC 3376 for the definition of the IGMP
type field.
</paragraph>
</reference>
</field>
<field name="sourceMacAddress" dataType="macAddress"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="56" applicability="data" status="current">
<description>
<paragraph>
The IEEE 802 source MAC address field.
</paragraph>
</description>
<reference>
<paragraph>
See IEEE.802-3.2002.
</paragraph>
</reference>
</field>
<field name="postSourceMacAddress" dataType="macAddress"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="81" applicability="data" status="current">
<description>
<paragraph>
The definition of this Information Element is identical
to the definition of Information Element
'sourceMacAddress', except that it reports a
potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
</paragraph>
</description>
<reference>
<paragraph>
See IEEE.802-3.2002.
</paragraph>
</reference>
</field>
<field name="vlanId" dataType="unsigned16"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="58" applicability="data" status="current">
<description>
Quittek, et al. Standards Track [Page 121]
RFC 5102 IPFIX Information Model January 2008
<paragraph>
The IEEE 802.1Q VLAN identifier (VID) extracted from the Tag
Control Information field that was attached to the IP packet.
</paragraph>
</description>
<reference>
<paragraph>
See IEEE.802-1Q.2003.
</paragraph>
</reference>
</field>
<field name="postVlanId" dataType="unsigned16"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="59" applicability="data" status="current">
<description>
<paragraph>
The definition of this Information Element is identical
to the definition of Information Element
'vlanId', except that it reports a
potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
</paragraph>
</description>
<reference>
<paragraph>
See IEEE.802-1Q.2003.
</paragraph>
</reference>
</field>
<field name="destinationMacAddress" dataType="macAddress"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="80" applicability="data" status="current">
<description>
<paragraph>
The IEEE 802 destination MAC address field.
</paragraph>
</description>
<reference>
<paragraph>
See IEEE.802-3.2002.
</paragraph>
</reference>
</field>
Quittek, et al. Standards Track [Page 122]
RFC 5102 IPFIX Information Model January 2008
<field name="postDestinationMacAddress" dataType="macAddress"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="57" applicability="data" status="current">
<description>
<paragraph>
The definition of this Information Element is identical
to the definition of Information Element
'destinationMacAddress', except that it reports a
potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
</paragraph>
</description>
<reference>
<paragraph>
See IEEE.802-3.2002.
</paragraph>
</reference>
</field>
<field name="wlanChannelId" dataType="unsigned8"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="146" applicability="data" status="current">
<description>
<paragraph>
The identifier of the 802.11 (Wi-Fi) channel used.
</paragraph>
</description>
<reference>
<paragraph>
See IEEE.802-11.1999.
</paragraph>
</reference>
</field>
<field name="wlanSSID" dataType="string"
group="subIpHeader"
elementId="147" applicability="data" status="current">
<description>
<paragraph>
The Service Set IDentifier (SSID) identifying an 802.11
(Wi-Fi) network used. According to IEEE.802-11.1999, the
SSID is encoded into a string of up to 32 characters.
</paragraph>
</description>
<reference>
<paragraph>
Quittek, et al. Standards Track [Page 123]
RFC 5102 IPFIX Information Model January 2008
See IEEE.802-11.1999.
</paragraph>
</reference>
</field>
<field name="mplsTopLabelTTL" dataType="unsigned8"
group="subIpHeader"
elementId="200" applicability="all" status="current">
<description>
<paragraph>
The TTL field from the top MPLS label stack entry,
i.e., the last label that was pushed.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032 for the specification of the
TTL field.
</paragraph>
</reference>
<units>hops</units>
</field>
<field name="mplsTopLabelExp" dataType="unsigned8"
group="subIpHeader"
dataTypeSemantics="flags"
elementId="203" applicability="all" status="current">
<description>
<paragraph>
The Exp field from the top MPLS label stack entry,
i.e., the last label that was pushed.
</paragraph>
<artwork>
Bits 0-4: Don't Care, value is irrelevant.
Bits 5-7: MPLS Exp field.
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| don't care | Exp |
+---+---+---+---+---+---+---+---+
</artwork>
</description>
<reference>
<paragraph>
See RFC 3032 for the specification of the Exp field.
See RFC 3270 for usage of the Exp field.
</paragraph>
</reference>
Quittek, et al. Standards Track [Page 124]
RFC 5102 IPFIX Information Model January 2008
</field>
<field name="postMplsTopLabelExp" dataType="unsigned8"
group="subIpHeader"
dataTypeSemantics="flags"
elementId="237" applicability="all" status="current">
<description>
<paragraph>
The definition of this Information Element is identical to the
definition of Information Element 'mplsTopLabelExp', except
that it reports a potentially modified value caused by a
middlebox function after the packet passed the Observation
Point.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032 for the specification of the Exp field.
See RFC 3270 for usage of the Exp field.
</paragraph>
</reference>
</field>
<field name="mplsLabelStackDepth" dataType="unsigned32"
group="subIpHeader"
elementId="202" applicability="all" status="current">
<description>
<paragraph>
The number of labels in the MPLS label stack.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032 for the specification of
the MPLS label stack.
</paragraph>
</reference>
<units>label stack entries</units>
</field>
<field name="mplsLabelStackLength" dataType="unsigned32"
group="subIpHeader"
elementId="201" applicability="all" status="current">
<description>
<paragraph>
The length of the MPLS label stack in units of octets.
</paragraph>
</description>
Quittek, et al. Standards Track [Page 125]
RFC 5102 IPFIX Information Model January 2008
<reference>
<paragraph>
See RFC 3032 for the specification of
the MPLS label stack.
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="mplsPayloadLength" dataType="unsigned32"
group="subIpHeader"
elementId="194" applicability="all" status="current">
<description>
<paragraph>
The size of the MPLS packet without the label stack.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3031 for the specification of
MPLS packets.
See RFC 3032 for the specification of
the MPLS label stack.
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="mplsTopLabelStackSection" dataType="octetArray"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="70" applicability="all" status="current">
<description>
<paragraph>
The Label, Exp, and S fields from the top MPLS label
stack entry, i.e., from the last label that was pushed.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
<artwork>
0 1 2
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Label | Exp |S|
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Label: Label Value, 20 bits
Quittek, et al. Standards Track [Page 126]
RFC 5102 IPFIX Information Model January 2008
Exp: Experimental Use, 3 bits
S: Bottom of Stack, 1 bit
</artwork>
</description>
<reference>
<paragraph>
See RFC 3032.
</paragraph>
</reference>
</field>
<field name="mplsLabelStackSection2" dataType="octetArray"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="71" applicability="all" status="current">
<description>
<paragraph>
The Label, Exp, and S fields from the label stack entry that
was pushed immediately before the label stack entry that would
be reported by mplsTopLabelStackSection. See the definition of
mplsTopLabelStackSection for further details.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032.
</paragraph>
</reference>
</field>
<field name="mplsLabelStackSection3" dataType="octetArray"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="72" applicability="all" status="current">
<description>
<paragraph>
The Label, Exp, and S fields from the label stack entry that
was pushed immediately before the label stack entry that would
be reported by mplsLabelStackSection2. See the definition of
mplsTopLabelStackSection for further details.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
</description>
Quittek, et al. Standards Track [Page 127]
RFC 5102 IPFIX Information Model January 2008
<reference>
<paragraph>
See RFC 3032.
</paragraph>
</reference>
</field>
<field name="mplsLabelStackSection4" dataType="octetArray"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="73" applicability="all" status="current">
<description>
<paragraph>
The Label, Exp, and S fields from the label stack entry that
was pushed immediately before the label stack entry that would
be reported by mplsLabelStackSection3. See the definition of
mplsTopLabelStackSection for further details.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032.
</paragraph>
</reference>
</field>
<field name="mplsLabelStackSection5" dataType="octetArray"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="74" applicability="all" status="current">
<description>
<paragraph>
The Label, Exp, and S fields from the label stack entry that
was pushed immediately before the label stack entry that would
be reported by mplsLabelStackSection4. See the definition of
mplsTopLabelStackSection for further details.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032.
</paragraph>
Quittek, et al. Standards Track [Page 128]
RFC 5102 IPFIX Information Model January 2008
</reference>
</field>
<field name="mplsLabelStackSection6" dataType="octetArray"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="75" applicability="all" status="current">
<description>
<paragraph>
The Label, Exp, and S fields from the label stack entry that
was pushed immediately before the label stack entry that would
be reported by mplsLabelStackSection5. See the definition of
mplsTopLabelStackSection for further details.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032.
</paragraph>
</reference>
</field>
<field name="mplsLabelStackSection7" dataType="octetArray"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="76" applicability="all" status="current">
<description>
<paragraph>
The Label, Exp, and S fields from the label stack entry that
was pushed immediately before the label stack entry that would
be reported by mplsLabelStackSection6. See the definition of
mplsTopLabelStackSection for further details.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032.
</paragraph>
</reference>
</field>
<field name="mplsLabelStackSection8" dataType="octetArray"
Quittek, et al. Standards Track [Page 129]
RFC 5102 IPFIX Information Model January 2008
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="77" applicability="all" status="current">
<description>
<paragraph>
The Label, Exp, and S fields from the label stack entry that
was pushed immediately before the label stack entry that would
be reported by mplsLabelStackSection7. See the definition of
mplsTopLabelStackSection for further details.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032.
</paragraph>
</reference>
</field>
<field name="mplsLabelStackSection9" dataType="octetArray"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="78" applicability="all" status="current">
<description>
<paragraph>
The Label, Exp, and S fields from the label stack entry that
was pushed immediately before the label stack entry that would
be reported by mplsLabelStackSection8. See the definition of
mplsTopLabelStackSection for further details.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032.
</paragraph>
</reference>
</field>
<field name="mplsLabelStackSection10" dataType="octetArray"
group="subIpHeader"
dataTypeSemantics="identifier"
elementId="79" applicability="all" status="current">
<description>
Quittek, et al. Standards Track [Page 130]
RFC 5102 IPFIX Information Model January 2008
<paragraph>
The Label, Exp, and S fields from the label stack entry that
was pushed immediately before the label stack entry that would
be reported by mplsLabelStackSection9. See the definition of
mplsTopLabelStackSection for further details.
</paragraph>
<paragraph>
The size of this Information Element is 3 octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3032.
</paragraph>
</reference>
</field>
<field name="ipPayloadLength" dataType="unsigned32"
group="derived"
elementId="204" applicability="all" status="current">
<description>
<paragraph>
The effective length of the IP payload.
</paragraph>
<paragraph>
For IPv4 packets, the value of this Information Element is
the difference between the total length of the IPv4 packet
(as reported by Information Element totalLengthIPv4) and the
length of the IPv4 header (as reported by Information Element
headerLengthIPv4).
</paragraph>
<paragraph>
For IPv6, the value of the Payload Length field
in the IPv6 header is reported except in the case that
the value of this field is zero and that there is a valid
jumbo payload option. In this case, the value of the
Jumbo Payload Length field in the jumbo payload option
is reported.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of
IPv4 packets.
See RFC 2460 for the specification of the
IPv6 payload length.
See RFC 2675 for the specification of the
IPv6 jumbo payload length.
Quittek, et al. Standards Track [Page 131]
RFC 5102 IPFIX Information Model January 2008
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="ipNextHopIPv4Address" dataType="ipv4Address"
group="derived"
dataTypeSemantics="identifier"
elementId="15" applicability="data" status="current">
<description>
<paragraph>
The IPv4 address of the next IPv4 hop.
</paragraph>
</description>
</field>
<field name="ipNextHopIPv6Address" dataType="ipv6Address"
group="derived"
dataTypeSemantics="identifier"
elementId="62" applicability="data" status="current">
<description>
<paragraph>
The IPv6 address of the next IPv6 hop.
</paragraph>
</description>
</field>
<field name="bgpSourceAsNumber" dataType="unsigned32"
group="derived"
dataTypeSemantics="identifier"
elementId="16" applicability="all" status="current">
<description>
<paragraph>
The autonomous system (AS) number of the source IP address.
If AS path information for this Flow is only available as
an unordered AS set (and not as an ordered AS sequence),
then the value of this Information Element is 0.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4271 for a description of BGP-4, and see RFC 1930
for the definition of the AS number.
</paragraph>
</reference>
</field>
<field name="bgpDestinationAsNumber" dataType="unsigned32"
Quittek, et al. Standards Track [Page 132]
RFC 5102 IPFIX Information Model January 2008
group="derived"
dataTypeSemantics="identifier"
elementId="17" applicability="all" status="current">
<description>
<paragraph>
The autonomous system (AS) number of the destination IP
address. If AS path information for this Flow is only
available as an unordered AS set (and not as an ordered AS
sequence), then the value of this Information Element is 0.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4271 for a description of BGP-4, and see RFC 1930 for
the definition of the AS number.
</paragraph>
</reference>
</field>
<field name="bgpNextAdjacentAsNumber" dataType="unsigned32"
group="derived"
dataTypeSemantics="identifier"
elementId="128" applicability="all" status="current">
<description>
<paragraph>
The autonomous system (AS) number of the first AS in the AS
path to the destination IP address. The path is deduced
by looking up the destination IP address of the Flow in the
BGP routing information base. If AS path information for
this Flow is only available as an unordered AS set (and not
as an ordered AS sequence), then the value of this Information
Element is 0.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4271 for a description of BGP-4, and
see RFC 1930 for the definition of the AS number.
</paragraph>
</reference>
</field>
<field name="bgpPrevAdjacentAsNumber" dataType="unsigned32"
group="derived"
dataTypeSemantics="identifier"
elementId="129" applicability="all" status="current">
<description>
<paragraph>
Quittek, et al. Standards Track [Page 133]
RFC 5102 IPFIX Information Model January 2008
The autonomous system (AS) number of the last AS in the AS
path from the source IP address. The path is deduced
by looking up the source IP address of the Flow in the BGP
routing information base. If AS path information for this
Flow is only available as an unordered AS set (and not as
an ordered AS sequence), then the value of this Information
Element is 0. In case of BGP asymmetry, the
bgpPrevAdjacentAsNumber might not be able to report the correct
value.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4271 for a description of BGP-4, and
see RFC 1930 for the definition of the AS number.
</paragraph>
</reference>
</field>
<field name="bgpNextHopIPv4Address" dataType="ipv4Address"
group="derived"
dataTypeSemantics="identifier"
elementId="18" applicability="all" status="current">
<description>
<paragraph>
The IPv4 address of the next (adjacent) BGP hop.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4271 for a description of BGP-4.
</paragraph>
</reference>
</field>
<field name="bgpNextHopIPv6Address" dataType="ipv6Address"
group="derived"
dataTypeSemantics="identifier"
elementId="63" applicability="all" status="current">
<description>
<paragraph>
The IPv6 address of the next (adjacent) BGP hop.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4271 for a description of BGP-4.
</paragraph>
Quittek, et al. Standards Track [Page 134]
RFC 5102 IPFIX Information Model January 2008
</reference>
</field>
<field name="mplsTopLabelType" dataType="unsigned8"
group="derived"
dataTypeSemantics="identifier"
elementId="46" applicability="data" status="current">
<description>
<paragraph>
This field identifies the control protocol that allocated the
top-of-stack label. Initial values for this field are
listed below. Further values may be assigned by IANA in
the MPLS label type registry.
</paragraph>
<artwork>
- 0x01 TE-MIDPT: Any TE tunnel mid-point or tail label
- 0x02 Pseudowire: Any PWE3 or Cisco AToM based label
- 0x03 VPN: Any label associated with VPN
- 0x04 BGP: Any label associated with BGP or BGP routing
- 0x05 LDP: Any label associated with dynamically assigned
labels using LDP
</artwork>
</description>
<reference>
<paragraph>
See RFC 3031 for the MPLS label structure.
See RFC 4364 for the association of MPLS labels
with Virtual Private Networks (VPNs).
See RFC 4271 for BGP and BGP routing.
See RFC 5036 for Label Distribution Protocol (LDP).
See the list of MPLS label types assigned by IANA at
http://www.iana.org/assignments/mpls-label-values.
</paragraph>
</reference>
</field>
<field name="mplsTopLabelIPv4Address" dataType="ipv4Address"
group="derived"
dataTypeSemantics="identifier"
elementId="47" applicability="data" status="current">
<description>
<paragraph>
The IPv4 address of the system that the MPLS top label will
cause this Flow to be forwarded to.
</paragraph>
</description>
<reference>
<paragraph>
Quittek, et al. Standards Track [Page 135]
RFC 5102 IPFIX Information Model January 2008
See RFC 3031 for the association between
MPLS labels and IP addresses.
</paragraph>
</reference>
</field>
<field name="mplsTopLabelIPv6Address" dataType="ipv6Address"
group="derived"
dataTypeSemantics="identifier"
elementId="140" applicability="data" status="current">
<description>
<paragraph>
The IPv6 address of the system that the MPLS top label will
cause this Flow to be forwarded to.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 3031 for the association between
MPLS labels and IP addresses.
</paragraph>
</reference>
</field>
<field name="mplsVpnRouteDistinguisher" dataType="octetArray"
group="derived"
dataTypeSemantics="identifier"
elementId="90" applicability="all" status="current">
<description>
<paragraph>
The value of the VPN route distinguisher of a corresponding
entry in a VPN routing and forwarding table. Route
distinguisher ensures that the same address can be used in
several different MPLS VPNs and that it is possible for BGP to
carry several completely different routes to that address, one
for each VPN. According to RFC 4364, the size of
mplsVpnRouteDistinguisher is 8 octets. However, in RFC 4382 an
octet string with flexible length was chosen for representing a
VPN route distinguisher by object MplsL3VpnRouteDistinguisher.
This choice was made in order to be open to future changes of
the size. This idea was adopted when choosing octetArray as
abstract data type for this Information Element. The maximum
length of this Information Element is 256 octets.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 4364 for the specification of the route
Quittek, et al. Standards Track [Page 136]
RFC 5102 IPFIX Information Model January 2008
distinguisher. See RFC 4382 for the specification
of the MPLS/BGP Layer 3 Virtual Private Network (VPN)
Management Information Base.
</paragraph>
</reference>
</field>
<field name="minimumIpTotalLength" dataType="unsigned64"
group="minMax"
elementId="25" applicability="all" status="current">
<description>
<paragraph>
Length of the smallest packet observed for this Flow.
The packet length includes the IP header(s) length and
the IP payload length.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of the
IPv4 total length.
See RFC 2460 for the specification of the
IPv6 payload length.
See RFC 2675 for the specification of the
IPv6 jumbo payload length.
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="maximumIpTotalLength" dataType="unsigned64"
group="minMax"
elementId="26" applicability="all" status="current">
<description>
<paragraph>
Length of the largest packet observed for this Flow.
The packet length includes the IP header(s) length and
the IP payload length.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the specification of the
IPv4 total length.
See RFC 2460 for the specification of the
IPv6 payload length.
See RFC 2675 for the specification of the
IPv6 jumbo payload length.
Quittek, et al. Standards Track [Page 137]
RFC 5102 IPFIX Information Model January 2008
</paragraph>
</reference>
<units>octets</units>
</field>
<field name="minimumTTL" dataType="unsigned8"
group="minMax"
elementId="52" applicability="data" status="current">
<description>
<paragraph>
Minimum TTL value observed for any packet in this Flow.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the definition of the IPv4
Time to Live field.
See RFC 2460 for the definition of the IPv6
Hop Limit field.
</paragraph>
</reference>
<units>hops</units>
</field>
<field name="maximumTTL" dataType="unsigned8"
group="minMax"
elementId="53" applicability="data" status="current">
<description>
<paragraph>
Maximum TTL value observed for any packet in this Flow.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 791 for the definition of the IPv4
Time to Live field.
See RFC 2460 for the definition of the IPv6
Hop Limit field.
</paragraph>
</reference>
<units>hops</units>
</field>
<field name="ipv4Options" dataType="unsigned32"
dataTypeSemantics="flags"
group="minMax"
elementId="208" applicability="all" status="current">
<description>
Quittek, et al. Standards Track [Page 138]
RFC 5102 IPFIX Information Model January 2008
<paragraph>
IPv4 options in packets of this Flow.
The information is encoded in a set of bit fields. For
each valid IPv4 option type, there is a bit in this set.
The bit is set to 1 if any observed packet of this Flow
contains the corresponding IPv4 option type. Otherwise,
if no observed packet of this Flow contained the
respective IPv4 option type, the value of the
corresponding bit is 0.
</paragraph>
<paragraph>
The list of valid IPv4 options is maintained by IANA.
Note that for identifying an option not just the 5-bit
Option Number, but all 8 bits of the Option Type need to
match one of the IPv4 options specified at
http://www.iana.org/assignments/ip-parameters.
</paragraph>
<paragraph>
Options are mapped to bits according to their option numbers.
Option number X is mapped to bit X.
The mapping is illustrated by the figure below.
</paragraph>
<artwork>
0 1 2 3 4 5 6 7
+------+------+------+------+------+------+------+------+
| EOOL | NOP | SEC | LSR | TS |E-SEC |CIPSO | RR | ...
+------+------+------+------+------+------+------+------+
8 9 10 11 12 13 14 15
+------+------+------+------+------+------+------+------+
... | SID | SSR | ZSU | MTUP | MTUR | FINN | VISA |ENCODE| ...
+------+------+------+------+------+------+------+------+
16 17 18 19 20 21 22 23
+------+------+------+------+------+------+------+------+
... |IMITD | EIP | TR |ADDEXT|RTRALT| SDB |NSAPA | DPS | ...
+------+------+------+------+------+------+------+------+
24 25 26 27 28 29 30 31
+------+------+------+------+------+------+------+------+
... | UMP | QS | to be assigned by IANA | EXP | |
+------+------+------+------+------+------+------+------+
Type Option
Bit Value Name Reference
---+-----+-------+------------------------------------
0 0 EOOL End of Options List, RFC 791
1 1 NOP No Operation, RFC 791
Quittek, et al. Standards Track [Page 139]
RFC 5102 IPFIX Information Model January 2008
2 130 SEC Security, RFC 1108
3 131 LSR Loose Source Route, RFC 791
4 68 TS Time Stamp, RFC 791
5 133 E-SEC Extended Security, RFC 1108
6 134 CIPSO Commercial Security
7 7 RR Record Route, RFC 791
8 136 SID Stream ID, RFC 791
9 137 SSR Strict Source Route, RFC 791
10 10 ZSU Experimental Measurement
11 11 MTUP (obsoleted) MTU Probe, RFC 1191
12 12 MTUR (obsoleted) MTU Reply, RFC 1191
13 205 FINN Experimental Flow Control
14 142 VISA Experimental Access Control
15 15 ENCODE
16 144 IMITD IMI Traffic Descriptor
17 145 EIP Extended Internet Protocol, RFC 1385
18 82 TR Traceroute, RFC 3193
19 147 ADDEXT Address Extension
20 148 RTRALT Router Alert, RFC 2113
21 149 SDB Selective Directed Broadcast
22 150 NSAPA NSAP Address
23 151 DPS Dynamic Packet State
24 152 UMP Upstream Multicast Pkt.
25 25 QS Quick-Start
30 30 EXP RFC3692-style Experiment
30 94 EXP RFC3692-style Experiment
30 158 EXP RFC3692-style Experiment
30 222 EXP RFC3692-style Experiment
... ... ... Further options numbers
may be assigned by IANA
</artwork>
</description>
<reference>
<paragraph>
See RFC 791 for the definition of IPv4 options.
See the list of IPv4 option numbers assigned by IANA
at http://www.iana.org/assignments/ip-parameters.
</paragraph>
</reference>
</field>
<field name="ipv6ExtensionHeaders" dataType="unsigned32"
dataTypeSemantics="flags"
group="minMax"
elementId="64" applicability="all" status="current">
<description>
<paragraph>
Quittek, et al. Standards Track [Page 140]
RFC 5102 IPFIX Information Model January 2008
IPv6 extension headers observed in packets of this Flow.
The information is encoded in a set of bit fields. For
each IPv6 option header, there is a bit in this set.
The bit is set to 1 if any observed packet of this Flow
contains the corresponding IPv6 extension header.
Otherwise, if no observed packet of this Flow contained
the respective IPv6 extension header, the value of the
corresponding bit is 0.
</paragraph>
<artwork>
0 1 2 3 4 5 6 7
+-----+-----+-----+-----+-----+-----+-----+-----+
| Res | FRA1| RH | FRA0| UNK | Res | HOP | DST | ...
+-----+-----+-----+-----+-----+-----+-----+-----+
8 9 10 11 12 13 14 15
+-----+-----+-----+-----+-----+-----+-----+-----+
... | PAY | AH | ESP | Reserved | ...
+-----+-----+-----+-----+-----+-----+-----+-----+
16 17 18 19 20 21 22 23
+-----+-----+-----+-----+-----+-----+-----+-----+
... | Reserved | ...
+-----+-----+-----+-----+-----+-----+-----+-----+
24 25 26 27 28 29 30 31
+-----+-----+-----+-----+-----+-----+-----+-----+
... | Reserved |
+-----+-----+-----+-----+-----+-----+-----+-----+
Bit IPv6 Option Description
0, Res Reserved
1, FRA1 44 Fragmentation header - not first fragment
2, RH 43 Routing header
3, FRA0 44 Fragment header - first fragment
4, UNK Unknown Layer 4 header
(compressed, encrypted, not supported)
5, Res Reserved
6, HOP 0 Hop-by-hop option header
7, DST 60 Destination option header
8, PAY 108 Payload compression header
9, AH 51 Authentication Header
10, ESP 50 Encrypted security payload
11 to 31 Reserved
</artwork>
</description>
<reference>
<paragraph>
See RFC 2460 for the general definition of
Quittek, et al. Standards Track [Page 141]
RFC 5102 IPFIX Information Model January 2008
IPv6 extension headers and for the specification of
the hop-by-hop options header, the routing header,
the fragment header, and the destination options header.
See RFC 4302 for the specification of the
authentication header.
See RFC 4303 for the specification of the
encapsulating security payload.
</paragraph>
</reference>
</field>
<field name="tcpControlBits" dataType="unsigned8"
dataTypeSemantics="flags"
group="minMax"
elementId="6" applicability="all" status="current">
<description>
<paragraph>
TCP control bits observed for packets of this Flow.
The information is encoded in a set of bit fields.
For each TCP control bit, there is a bit in this
set. A bit is set to 1 if any observed packet of this
Flow has the corresponding TCP control bit set to 1.
A value of 0 for a bit indicates that the corresponding
bit was not set in any of the observed packets
of this Flow.
</paragraph>
<artwork>
0 1 2 3 4 5 6 7
+-----+-----+-----+-----+-----+-----+-----+-----+
| Reserved | URG | ACK | PSH | RST | SYN | FIN |
+-----+-----+-----+-----+-----+-----+-----+-----+
Reserved: Reserved for future use by TCP. Must be zero.
URG: Urgent Pointer field significant
ACK: Acknowledgment field significant
PSH: Push Function
RST: Reset the connection
SYN: Synchronize sequence numbers
FIN: No more data from sender
</artwork>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of
the TCP control bits in the TCP header.
</paragraph>
</reference>
</field>
Quittek, et al. Standards Track [Page 142]
RFC 5102 IPFIX Information Model January 2008
<field name="tcpOptions" dataType="unsigned64"
dataTypeSemantics="flags"
group="minMax"
elementId="209" applicability="all" status="current">
<description>
<paragraph>
TCP options in packets of this Flow.
The information is encoded in a set of bit fields. For
each TCP option, there is a bit in this set.
The bit is set to 1 if any observed packet of this Flow
contains the corresponding TCP option.
Otherwise, if no observed packet of this Flow contained
the respective TCP option, the value of the
corresponding bit is 0.
</paragraph>
<paragraph>
Options are mapped to bits according to their option
numbers. Option number X is mapped to bit X.
TCP option numbers are maintained by IANA.
</paragraph>
<artwork>
0 1 2 3 4 5 6 7
+-----+-----+-----+-----+-----+-----+-----+-----+
| 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | ...
+-----+-----+-----+-----+-----+-----+-----+-----+
8 9 10 11 12 13 14 15
+-----+-----+-----+-----+-----+-----+-----+-----+
... | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 |...
+-----+-----+-----+-----+-----+-----+-----+-----+
16 17 18 19 20 21 22 23
+-----+-----+-----+-----+-----+-----+-----+-----+
... | 16 | 17 | 18 | 19 | 20 | 21 | 22 | 23 |...
+-----+-----+-----+-----+-----+-----+-----+-----+
. . .
56 57 58 59 60 61 62 63
+-----+-----+-----+-----+-----+-----+-----+-----+
... | 56 | 57 | 58 | 59 | 60 | 61 | 62 | 63 |
+-----+-----+-----+-----+-----+-----+-----+-----+
</artwork>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of TCP options.
See the list of TCP option numbers assigned by IANA
Quittek, et al. Standards Track [Page 143]
RFC 5102 IPFIX Information Model January 2008
at http://www.iana.org/assignments/tcp-parameters.
</paragraph>
</reference>
</field>
<field name="flowStartSeconds" dataType="dateTimeSeconds"
group="timestamp"
elementId="150" applicability="data" status="current">
<description>
<paragraph>
The absolute timestamp of the first packet of this Flow.
</paragraph>
</description>
<units>seconds</units>
</field>
<field name="flowEndSeconds" dataType="dateTimeSeconds"
group="timestamp"
elementId="151" applicability="data" status="current">
<description>
<paragraph>
The absolute timestamp of the last packet of this Flow.
</paragraph>
</description>
<units>seconds</units>
</field>
<field name="flowStartMilliseconds" dataType="dateTimeMilliseconds"
group="timestamp"
elementId="152" applicability="data" status="current">
<description>
<paragraph>
The absolute timestamp of the first packet of this Flow.
</paragraph>
</description>
<units>milliseconds</units>
</field>
<field name="flowEndMilliseconds" dataType="dateTimeMilliseconds"
group="timestamp"
elementId="153" applicability="data" status="current">
<description>
<paragraph>
The absolute timestamp of the last packet of this Flow.
</paragraph>
</description>
<units>milliseconds</units>
</field>
Quittek, et al. Standards Track [Page 144]
RFC 5102 IPFIX Information Model January 2008
<field name="flowStartMicroseconds" dataType="dateTimeMicroseconds"
group="timestamp"
elementId="154" applicability="data" status="current">
<description>
<paragraph>
The absolute timestamp of the first packet of this Flow.
</paragraph>
</description>
<units>microseconds</units>
</field>
<field name="flowEndMicroseconds" dataType="dateTimeMicroseconds"
group="timestamp"
elementId="155" applicability="data" status="current">
<description>
<paragraph>
The absolute timestamp of the last packet of this Flow.
</paragraph>
</description>
<units>microseconds</units>
</field>
<field name="flowStartNanoseconds" dataType="dateTimeNanoseconds"
group="timestamp"
elementId="156" applicability="data" status="current">
<description>
<paragraph>
The absolute timestamp of the first packet of this Flow.
</paragraph>
</description>
<units>nanoseconds</units>
</field>
<field name="flowEndNanoseconds" dataType="dateTimeNanoseconds"
group="timestamp"
elementId="157" applicability="data" status="current">
<description>
<paragraph>
The absolute timestamp of the last packet of this Flow.
</paragraph>
</description>
<units>nanoseconds</units>
</field>
<field name="flowStartDeltaMicroseconds" dataType="unsigned32"
group="timestamp"
elementId="158" applicability="data" status="current">
<description>
Quittek, et al. Standards Track [Page 145]
RFC 5102 IPFIX Information Model January 2008
<paragraph>
This is a relative timestamp only valid within the scope
of a single IPFIX Message. It contains the negative time
offset of the first observed packet of this Flow relative
to the export time specified in the IPFIX Message Header.
</paragraph>
</description>
<reference>
<paragraph>
See the IPFIX protocol specification [RFC5101] for the
definition of the IPFIX Message Header.
</paragraph>
</reference>
<units>microseconds</units>
</field>
<field name="flowEndDeltaMicroseconds" dataType="unsigned32"
group="timestamp"
elementId="159" applicability="data" status="current">
<description>
<paragraph>
This is a relative timestamp only valid within the scope
of a single IPFIX Message. It contains the negative time
offset of the last observed packet of this Flow relative
to the export time specified in the IPFIX Message Header.
</paragraph>
</description>
<reference>
<paragraph>
See the IPFIX protocol specification [RFC5101] for the
definition of the IPFIX Message Header.
</paragraph>
</reference>
<units>microseconds</units>
</field>
<field name="systemInitTimeMilliseconds"
dataType="dateTimeMilliseconds"
group="timestamp"
elementId="160" applicability="data" status="current">
<description>
<paragraph>
The absolute timestamp of the last (re-)initialization of the
IPFIX Device.
</paragraph>
</description>
<units>milliseconds</units>
</field>
Quittek, et al. Standards Track [Page 146]
RFC 5102 IPFIX Information Model January 2008
<field name="flowStartSysUpTime" dataType="unsigned32"
group="timestamp"
elementId="22" applicability="data" status="current">
<description>
<paragraph>
The relative timestamp of the first packet of this Flow.
It indicates the number of milliseconds since the
last (re-)initialization of the IPFIX Device (sysUpTime).
</paragraph>
</description>
<units>milliseconds</units>
</field>
<field name="flowEndSysUpTime" dataType="unsigned32"
group="timestamp"
elementId="21" applicability="data" status="current">
<description>
<paragraph>
The relative timestamp of the last packet of this Flow.
It indicates the number of milliseconds since the
last (re-)initialization of the IPFIX Device (sysUpTime).
</paragraph>
</description>
<units>milliseconds</units>
</field>
<field name="octetDeltaCount" dataType="unsigned64"
dataTypeSemantics="deltaCounter"
group="flowCounter"
elementId="1" applicability="data" status="current">
<description>
<paragraph>
The number of octets since the previous report (if any)
in incoming packets for this Flow at the Observation Point.
The number of octets includes IP header(s) and IP payload.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="postOctetDeltaCount" dataType="unsigned64"
dataTypeSemantics="deltaCounter"
group="flowCounter"
elementId="23" applicability="data" status="current">
<description>
<paragraph>
The definition of this Information Element is identical
to the definition of Information Element
Quittek, et al. Standards Track [Page 147]
RFC 5102 IPFIX Information Model January 2008
'octetDeltaCount', except that it reports a
potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="octetDeltaSumOfSquares" dataType="unsigned64"
group="flowCounter"
elementId="198" applicability="data" status="current">
<description>
<paragraph>
The sum of the squared numbers of octets per incoming
packet since the previous report (if any) for this
Flow at the Observation Point.
The number of octets includes IP header(s) and IP payload.
</paragraph>
</description>
</field>
<field name="octetTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="85" applicability="all" status="current">
<description>
<paragraph>
The total number of octets in incoming packets
for this Flow at the Observation Point since the Metering
Process (re-)initialization for this Observation Point. The
number of octets includes IP header(s) and IP payload.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="postOctetTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="171" applicability="all" status="current">
<description>
<paragraph>
The definition of this Information Element is identical
to the definition of Information Element
'octetTotalCount', except that it reports a
potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
</paragraph>
Quittek, et al. Standards Track [Page 148]
RFC 5102 IPFIX Information Model January 2008
</description>
<units>octets</units>
</field>
<field name="octetTotalSumOfSquares" dataType="unsigned64"
group="flowCounter"
elementId="199" applicability="all" status="current">
<description>
<paragraph>
The total sum of the squared numbers of octets in incoming
packets for this Flow at the Observation Point since the
Metering Process (re-)initialization for this Observation
Point. The number of octets includes IP header(s) and IP
payload.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="packetDeltaCount" dataType="unsigned64"
dataTypeSemantics="deltaCounter"
group="flowCounter"
elementId="2" applicability="data" status="current">
<description>
<paragraph>
The number of incoming packets since the previous report
(if any) for this Flow at the Observation Point.
</paragraph>
</description>
<units>packets</units>
</field>
<field name="postPacketDeltaCount" dataType="unsigned64"
dataTypeSemantics="deltaCounter"
group="flowCounter"
elementId="24" applicability="data" status="current">
<description>
<paragraph>
The definition of this Information Element is identical
to the definition of Information Element
'packetDeltaCount', except that it reports a
potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
</paragraph>
</description>
<units>packets</units>
</field>
Quittek, et al. Standards Track [Page 149]
RFC 5102 IPFIX Information Model January 2008
<field name="packetTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="86" applicability="all" status="current">
<description>
<paragraph>
The total number of incoming packets for this Flow
at the Observation Point since the Metering Process
(re-)initialization for this Observation Point.
</paragraph>
</description>
<units>packets</units>
</field>
<field name="postPacketTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="172" applicability="all" status="current">
<description>
<paragraph>
The definition of this Information Element is identical
to the definition of Information Element
'packetTotalCount', except that it reports a
potentially modified value caused by a middlebox
function after the packet passed the Observation Point.
</paragraph>
</description>
<units>packets</units>
</field>
<field name="droppedOctetDeltaCount" dataType="unsigned64"
dataTypeSemantics="deltaCounter"
group="flowCounter"
elementId="132" applicability="data" status="current">
<description>
<paragraph>
The number of octets since the previous report (if any)
in packets of this Flow dropped by packet treatment.
The number of octets includes IP header(s) and IP payload.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="droppedPacketDeltaCount" dataType="unsigned64"
dataTypeSemantics="deltaCounter"
group="flowCounter"
elementId="133" applicability="data" status="current">
Quittek, et al. Standards Track [Page 150]
RFC 5102 IPFIX Information Model January 2008
<description>
<paragraph>
The number of packets since the previous report (if any)
of this Flow dropped by packet treatment.
</paragraph>
</description>
<units>packets</units>
</field>
<field name="droppedOctetTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="134" applicability="data" status="current">
<description>
<paragraph>
The total number of octets in packets of this Flow dropped
by packet treatment since the Metering Process
(re-)initialization for this Observation Point.
The number of octets includes IP header(s) and IP payload.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="droppedPacketTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="135" applicability="data" status="current">
<description>
<paragraph>
The number of packets of this Flow dropped by packet
treatment since the Metering Process
(re-)initialization for this Observation Point.
</paragraph>
</description>
<units>packets</units>
</field>
<field name="postMCastPacketDeltaCount" dataType="unsigned64"
dataTypeSemantics="deltaCounter"
group="flowCounter"
elementId="19" applicability="data" status="current">
<description>
<paragraph>
The number of outgoing multicast packets since the
previous report (if any) sent for packets of this Flow
by a multicast daemon within the Observation Domain.
This property cannot necessarily be observed at the
Quittek, et al. Standards Track [Page 151]
RFC 5102 IPFIX Information Model January 2008
Observation Point, but may be retrieved by other means.
</paragraph>
</description>
<units>packets</units>
</field>
<field name="postMCastOctetDeltaCount" dataType="unsigned64"
dataTypeSemantics="deltaCounter"
group="flowCounter"
elementId="20" applicability="data" status="current">
<description>
<paragraph>
The number of octets since the previous report (if any)
in outgoing multicast packets sent for packets of this
Flow by a multicast daemon within the Observation Domain.
This property cannot necessarily be observed at the
Observation Point, but may be retrieved by other means.
The number of octets includes IP header(s) and IP payload.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="postMCastPacketTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="174" applicability="data" status="current">
<description>
<paragraph>
The total number of outgoing multicast packets sent for
packets of this Flow by a multicast daemon within the
Observation Domain since the Metering Process
(re-)initialization. This property cannot necessarily
be observed at the Observation Point, but may be retrieved
by other means.
</paragraph>
</description>
<units>packets</units>
</field>
<field name="postMCastOctetTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="175" applicability="data" status="current">
<description>
<paragraph>
The total number of octets in outgoing multicast packets
sent for packets of this Flow by a multicast daemon in the
Quittek, et al. Standards Track [Page 152]
RFC 5102 IPFIX Information Model January 2008
Observation Domain since the Metering Process
(re-)initialization. This property cannot necessarily be
observed at the Observation Point, but may be retrieved by
other means.
The number of octets includes IP header(s) and IP payload.
</paragraph>
</description>
<units>octets</units>
</field>
<field name="tcpSynTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="218" applicability="data" status="current">
<description>
<paragraph>
The total number of packets of this Flow with
TCP "Synchronize sequence numbers" (SYN) flag set.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP SYN flag.
</paragraph>
</reference>
<units>packets</units>
</field>
<field name="tcpFinTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="219" applicability="data" status="current">
<description>
<paragraph>
The total number of packets of this Flow with
TCP "No more data from sender" (FIN) flag set.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP FIN flag.
</paragraph>
</reference>
<units>packets</units>
</field>
<field name="tcpRstTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
Quittek, et al. Standards Track [Page 153]
RFC 5102 IPFIX Information Model January 2008
group="flowCounter"
elementId="220" applicability="data" status="current">
<description>
<paragraph>
The total number of packets of this Flow with
TCP "Reset the connection" (RST) flag set.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP RST flag.
</paragraph>
</reference>
<units>packets</units>
</field>
<field name="tcpPshTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="221" applicability="data" status="current">
<description>
<paragraph>
The total number of packets of this Flow with
TCP "Push Function" (PSH) flag set.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP PSH flag.
</paragraph>
</reference>
<units>packets</units>
</field>
<field name="tcpAckTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="222" applicability="data" status="current">
<description>
<paragraph>
The total number of packets of this Flow with
TCP "Acknowledgment field significant" (ACK) flag set.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP ACK flag.
</paragraph>
Quittek, et al. Standards Track [Page 154]
RFC 5102 IPFIX Information Model January 2008
</reference>
<units>packets</units>
</field>
<field name="tcpUrgTotalCount" dataType="unsigned64"
dataTypeSemantics="totalCounter"
group="flowCounter"
elementId="223" applicability="data" status="current">
<description>
<paragraph>
The total number of packets of this Flow with
TCP "Urgent Pointer field significant" (URG) flag set.
</paragraph>
</description>
<reference>
<paragraph>
See RFC 793 for the definition of the TCP URG flag.
</paragraph>
</reference>
<units>packets</units>
</field>
<field name="flowActiveTimeout" dataType="unsigned16"
group="misc"
elementId="36" applicability="all" status="current">
<description>
<paragraph>
The number of seconds after which an active Flow is timed out
anyway, even if there is still a continuous flow of packets.
</paragraph>
</description>
<units>seconds</units>
</field>
<field name="flowIdleTimeout" dataType="unsigned16"
group="misc"
elementId="37" applicability="all" status="current">
<description>
<paragraph>
A Flow is considered to be timed out if no packets belonging
to the Flow have been observed for the number of seconds
specified by this field.
</paragraph>
</description>
<units>seconds</units>
</field>
<field name="flowEndReason" dataType="unsigned8"
Quittek, et al. Standards Track [Page 155]
RFC 5102 IPFIX Information Model January 2008
group="misc"
dataTypeSemantics="identifier"
elementId="136" applicability="data" status="current">
<description>
<paragraph>
The reason for Flow termination. The range of values includes
the following:
</paragraph>
<artwork>
0x01: idle timeout
The Flow was terminated because it was considered to be
idle.
0x02: active timeout
The Flow was terminated for reporting purposes while it was
still active, for example, after the maximum lifetime of
unreported Flows was reached.
0x03: end of Flow detected
The Flow was terminated because the Metering Process
detected signals indicating the end of the Flow,
for example, the TCP FIN flag.
0x04: forced end
The Flow was terminated because of some external event,
for example, a shutdown of the Metering Process initiated
by a network management application.
0x05: lack of resources
The Flow was terminated because of lack of resources
available to the Metering Process and/or the Exporting
Process.
</artwork>
</description>
</field>
<field name="flowDurationMilliseconds" dataType="unsigned32"
group="misc"
elementId="161" applicability="data" status="current">
<description>
<paragraph>
The difference in time between the first observed packet
of this Flow and the last observed packet of this Flow.
</paragraph>
</description>
<units>milliseconds</units>
</field>
<field name="flowDurationMicroseconds" dataType="unsigned32"
group="misc"
elementId="162" applicability="data" status="current">
<description>
Quittek, et al. Standards Track [Page 156]
RFC 5102 IPFIX Information Model January 2008
<paragraph>
The difference in time between the first observed packet
of this Flow and the last observed packet of this Flow.
</paragraph>
</description>
<units>microseconds</units>
</field>
<field name="flowDirection" dataType="unsigned8"
dataTypeSemantics="identifier"
group="misc"
elementId="61" applicability="data" status="current">
<description>
<paragraph>
The direction of the Flow observed at the Observation
Point. There are only two values defined.
</paragraph>
<artwork>
0x00: ingress flow
0x01: egress flow
</artwork>
</description>
</field>
<field name="paddingOctets" dataType="octetArray"
group="padding"
elementId="210" applicability="option" status="current">
<description>
<paragraph>
The value of this Information Element is always a sequence of
0x00 values.
</paragraph>
</description>
</field>
</fieldDefinitions>
Appendix B. XML Specification of Abstract Data Types
This appendix contains a machine-readable description of the abstract
data types to be used for IPFIX Information Elements and a machine-
readable description of the template used for defining IPFIX
Information Elements. Note that this appendix is of informational
nature, while the text in Sections 2 and 3 (generated from this
appendix) is normative.
At the same time, this appendix is also an XML schema that was used
for creating the XML specification of Information Elements in
Quittek, et al. Standards Track [Page 157]
RFC 5102 IPFIX Information Model January 2008
Appendix A. It may also be used for specifying further Information
Elements in extensions of the IPFIX information model. This schema
and its namespace are registered by IANA at
http://www.iana.org/assignments/xml-registry/schema/ipfix.xsd.
<?xml version="1.0" encoding="UTF-8"?>
<schema targetNamespace="urn:ietf:params:xml:ns:ipfix-info"
xmlns:ipfix="urn:ietf:params:xml:ns:ipfix-info"
xmlns="http://www.w3.org/2001/XMLSchema"
elementFormDefault="qualified">
<simpleType name="dataType">
<restriction base="string">
<enumeration value="unsigned8">
<annotation>
<documentation>The type "unsigned8" represents a
non-negative integer value in the range of 0 to 255.
</documentation>
</annotation>
</enumeration>
<enumeration value="unsigned16">
<annotation>
<documentation>The type "unsigned16" represents a
non-negative integer value in the range of 0 to 65535.
</documentation>
</annotation>
</enumeration>
<enumeration value="unsigned32">
<annotation>
<documentation>The type "unsigned32" represents a
non-negative integer value in the range of 0 to
4294967295.
</documentation>
</annotation>
</enumeration>
<enumeration value="unsigned64">
<annotation>
<documentation>The type "unsigned64" represents a
non-negative integer value in the range of 0 to
18446744073709551615.
</documentation>
</annotation>
</enumeration>
Quittek, et al. Standards Track [Page 158]
RFC 5102 IPFIX Information Model January 2008
<enumeration value="signed8">
<annotation>
<documentation>The type "signed8" represents
an integer value in the range of -128 to 127.
</documentation>
</annotation>
</enumeration>
<enumeration value="signed16">
<annotation>
<documentation>The type "signed16" represents an
integer value in the range of -32768 to 32767.
</documentation>
</annotation>
</enumeration>
<enumeration value="signed32">
<annotation>
<documentation>The type "signed32" represents an
integer value in the range of -2147483648 to
2147483647.
</documentation>
</annotation>
</enumeration>
<enumeration value="signed64">
<annotation>
<documentation>The type "signed64" represents an
integer value in the range of -9223372036854775808
to 9223372036854775807.
</documentation>
</annotation>
</enumeration>
<enumeration value="float32">
<annotation>
<documentation>The type "float32" corresponds to an IEEE
single-precision 32-bit floating point type as defined
in [IEEE.754.1985].
</documentation>
</annotation>
</enumeration>
<enumeration value="float64">
<annotation>
<documentation>The type "float64" corresponds to an IEEE
double-precision 64-bit floating point type as defined
in [IEEE.754.1985].
Quittek, et al. Standards Track [Page 159]
RFC 5102 IPFIX Information Model January 2008
</documentation>
</annotation>
</enumeration>
<enumeration value="boolean">
<annotation>
<documentation>The type "boolean" represents a binary
value. The only allowed values are "true" and "false".
</documentation>
</annotation>
</enumeration>
<enumeration value="macAddress">
<annotation>
<documentation>The type "macAddress" represents a
string of 6 octets.
</documentation>
</annotation>
</enumeration>
<enumeration value="octetArray">
<annotation>
<documentation>The type "octetArray" represents a
finite-length string of octets.
</documentation>
</annotation>
</enumeration>
<enumeration value="string">
<annotation>
<documentation>
The type "string" represents a finite-length string
of valid characters from the Unicode character encoding
set [ISO.10646-1.1993]. Unicode allows for ASCII
[ISO.646.1991] and many other international character
sets to be used.
</documentation>
</annotation>
</enumeration>
<enumeration value="dateTimeSeconds">
<annotation>
<documentation>
The type "dateTimeSeconds" represents a time value
in units of seconds based on coordinated universal time
(UTC). The choice of an epoch, for example, 00:00 UTC,
January 1, 1970, is left to corresponding encoding
specifications for this type, for example, the IPFIX
Quittek, et al. Standards Track [Page 160]
RFC 5102 IPFIX Information Model January 2008
protocol specification. Leap seconds are excluded.
Note that transformation of values might be required
between different encodings if different epoch values
are used.
</documentation>
</annotation>
</enumeration>
<enumeration value="dateTimeMilliseconds">
<annotation>
<documentation>The type "dateTimeMilliseconds" represents
a time value in units of milliseconds
based on coordinated universal time (UTC).
The choice of an epoch, for example, 00:00 UTC,
January 1, 1970, is left to corresponding encoding
specifications for this type, for example, the IPFIX
protocol specification. Leap seconds are excluded.
Note that transformation of values might be required
between different encodings if different epoch values
are used.
</documentation>
</annotation>
</enumeration>
<enumeration value="dateTimeMicroseconds">
<annotation>
<documentation>The type "dateTimeMicroseconds" represents
a time value in units of microseconds
based on coordinated universal time (UTC).
The choice of an epoch, for example, 00:00 UTC,
January 1, 1970, is left to corresponding encoding
specifications for this type, for example, the IPFIX
protocol specification. Leap seconds are excluded.
Note that transformation of values might be required
between different encodings if different epoch values
are used.
</documentation>
</annotation>
</enumeration>
<enumeration value="dateTimeNanoseconds">
<annotation>
<documentation>The type "dateTimeNanoseconds" represents
a time value in units of nanoseconds
based on coordinated universal time (UTC).
The choice of an epoch, for example, 00:00 UTC,
January 1, 1970, is left to corresponding encoding
specifications for this type, for example, the IPFIX
Quittek, et al. Standards Track [Page 161]
RFC 5102 IPFIX Information Model January 2008
protocol specification. Leap seconds are excluded.
Note that transformation of values might be required
between different encodings if different epoch values
are used.
</documentation>
</annotation>
</enumeration>
<enumeration value="ipv4Address">
<annotation>
<documentation>The type "ipv4Address" represents a value
of an IPv4 address.
</documentation>
</annotation>
</enumeration>
<enumeration value="ipv6Address">
<annotation>
<documentation>The type "ipv6Address" represents a value
of an IPv6 address.
</documentation>
</annotation>
</enumeration>
</restriction>
</simpleType>
<simpleType name="dataTypeSemantics">
<restriction base="string">
<enumeration value="quantity">
<annotation>
<documentation>
A quantity value represents a discrete
measured value pertaining to the record. This is
distinguished from counters that represent an ongoing
measured value whose "odometer" reading is captured as
part of a given record. If no semantic qualifier is
given, the Information Elements that have an integral
data type should behave as a quantity.
</documentation>
</annotation>
</enumeration>
<enumeration value="totalCounter">
<annotation>
<documentation>
An integral value reporting the value of a counter.
Counters are unsigned and wrap back to zero after
reaching the limit of the type. For example, an
unsigned64 with counter semantics will continue to
Quittek, et al. Standards Track [Page 162]
RFC 5102 IPFIX Information Model January 2008
increment until reaching the value of 2**64 - 1. At
this point, the next increment will wrap its value to
zero and continue counting from zero. The semantics
of a total counter is similar to the semantics of
counters used in SNMP, such as Counter32 defined in
RFC 2578 [RFC2578]. The only difference between total
counters and counters used in SNMP is that the total
counters have an initial value of 0. A total counter
counts independently of the export of its value.
</documentation>
</annotation>
</enumeration>
<enumeration value="deltaCounter">
<annotation>
<documentation>
An integral value reporting the value of a counter.
Counters are unsigned and wrap back to zero after
reaching the limit of the type. For example, an
unsigned64 with counter semantics will continue to
increment until reaching the value of 2**64 - 1. At
this point, the next increment will wrap its value to
zero and continue counting from zero. The semantics
of a delta counter is similar to the semantics of
counters used in SNMP, such as Counter32 defined in
RFC 2578 [RFC2578]. The only difference between delta
counters and counters used in SNMP is that the delta
counters have an initial value of 0. A delta counter
is reset to 0 each time its value is exported.
</documentation>
</annotation>
</enumeration>
<enumeration value="identifier">
<annotation>
<documentation>
An integral value that serves as an identifier.
Specifically, mathematical operations on two
identifiers (aside from the equality operation) are
meaningless. For example, Autonomous System ID 1 *
Autonomous System ID 2 is meaningless.
</documentation>
</annotation>
</enumeration>
<enumeration value="flags">
<annotation>
<documentation>
Quittek, et al. Standards Track [Page 163]
RFC 5102 IPFIX Information Model January 2008
An integral value that actually represents a set of
bit fields. Logical operations are appropriate on
such values, but not other mathematical operations.
Flags should always be of an unsigned type.
</documentation>
</annotation>
</enumeration>
</restriction>
</simpleType>
<simpleType name="applicability">
<restriction base="string">
<enumeration value="data">
<annotation>
<documentation>
Used for Information Elements that are applicable to
Flow Records only.
</documentation>
</annotation>
</enumeration>
<enumeration value="option">
<annotation>
<documentation>
Used for Information Elements that are applicable to
option records only.
</documentation>
</annotation>
</enumeration>
<enumeration value="all">
<annotation>
<documentation>
Used for Information Elements that are applicable to
Flow Records as well as to option records.
</documentation>
</annotation>
</enumeration>
</restriction>
</simpleType>
<simpleType name="status">
<restriction base="string">
<enumeration value="current">
<annotation>
<documentation>
Indicates that the Information Element definition
is current and valid.
Quittek, et al. Standards Track [Page 164]
RFC 5102 IPFIX Information Model January 2008
</documentation>
</annotation>
</enumeration>
<enumeration value="deprecated">
<annotation>
<documentation>
Indicates that the Information Element definition is
obsolete, but it permits new/continued implementation
in order to foster interoperability with older/existing
implementations.
</documentation>
</annotation>
</enumeration>
<enumeration value="obsolete">
<annotation>
<documentation>
Indicates that the Information Element definition is
obsolete and should not be implemented and/or can be
removed if previously implemented.
</documentation>
</annotation>
</enumeration>
</restriction>
</simpleType>
<complexType name="text">
<choice maxOccurs="unbounded" minOccurs="0">
<element name="paragraph">
<complexType mixed="true">
<sequence>
<element maxOccurs="unbounded" minOccurs="0"
name="xref">
<complexType>
<attribute name="target" type="string"
use="required"/>
</complexType>
</element>
</sequence>
</complexType>
</element>
<element name="artwork">
<simpleType>
<restriction base="string"/>
</simpleType>
</element>
</choice>
</complexType>
Quittek, et al. Standards Track [Page 165]
RFC 5102 IPFIX Information Model January 2008
<simpleType name="range">
<restriction base="string"/>
</simpleType>
<element name="fieldDefinitions">
<complexType>
<sequence>
<element maxOccurs="unbounded" minOccurs="1" name="field">
<complexType>
<sequence>
<element maxOccurs="1" minOccurs="1" name="description"
type="ipfix:text">
<annotation>
<documentation>
The semantics of this Information Element.
Describes how this Information Element is
derived from the Flow or other information
available to the observer.
</documentation>
</annotation>
</element>
<element maxOccurs="1" minOccurs="0" name="reference"
type="ipfix:text">
<annotation>
<documentation>
Identifies additional specifications that more
precisely define this item or provide additional
context for its use.
</documentation>
</annotation>
</element>
<element maxOccurs="1" minOccurs="0" name="units"
type="string">
<annotation>
<documentation>
If the Information Element is a measure of some
kind, the units identify what the measure is.
</documentation>
</annotation>
</element>
<element maxOccurs="1" minOccurs="0" name="range"
type="ipfix:range">
<annotation>
<documentation>
Some Information Elements may only be able to
take on a restricted set of values that can be
Quittek, et al. Standards Track [Page 166]
RFC 5102 IPFIX Information Model January 2008
expressed as a range (e.g., 0 through 511
inclusive). If this is the case, the valid
inclusive range should be specified.
</documentation>
</annotation>
</element>
</sequence>
<attribute name="name" type="string" use="required">
<annotation>
<documentation>
A unique and meaningful name for the Information
Element.
</documentation>
</annotation>
</attribute>
<attribute name="dataType" type="ipfix:dataType"
use="required">
<annotation>
<documentation>
One of the types listed in Section 3.1 of this
document or in a future extension of the
information model. The type space for attributes
is constrained to facilitate implementation. The
existing type space does however encompass most
basic types used in modern programming languages,
as well as some derived types (such as ipv4Address)
that are common to this domain and useful
to distinguish.
</documentation>
</annotation>
</attribute>
<attribute name="dataTypeSemantics"
type="ipfix:dataTypeSemantics" use="optional">
<annotation>
<documentation>
The integral types may be qualified by additional
semantic details. Valid values for the data type
semantics are specified in Section 3.2 of this
document or in a future extension of the
information model.
</documentation>
</annotation>
</attribute>
<attribute name="elementId" type="nonNegativeInteger"
Quittek, et al. Standards Track [Page 167]
RFC 5102 IPFIX Information Model January 2008
use="required">
<annotation>
<documentation>
A numeric identifier of the Information Element.
If this identifier is used without an enterprise
identifier (see [RFC5101] and
enterpriseId below), then it is globally unique
and the list of allowed values is administered by
IANA. It is used for compact identification of an
Information Element when encoding Templates in the
protocol.
</documentation>
</annotation>
</attribute>
<attribute name="enterpriseId" type="nonNegativeInteger"
use="optional">
<annotation>
<documentation>
Enterprises may wish to define Information Elements
without registering them with IANA, for example,
for enterprise-internal purposes. For such
Information Elements, the Information Element
identifier described above is not sufficient when
the Information Element is used outside the
enterprise. If specifications of
enterprise-specific Information Elements are made
public and/or if enterprise-specific identifiers
are used by the IPFIX protocol outside the
enterprise, then the enterprise-specific
identifier MUST be made globally unique by
combining it with an enterprise identifier.
Valid values for the enterpriseId are
defined by IANA as Structure of Management
Information (SMI) network management private
enterprise codes. They are defined at
http://www.iana.org/assignments/enterprise-numbers.
</documentation>
</annotation>
</attribute>
<attribute name="applicability"
type="ipfix:applicability" use="optional">
<annotation>
<documentation>
This property of an Information
Element indicates in which kind of records the
Information Element can be used.
Quittek, et al. Standards Track [Page 168]
RFC 5102 IPFIX Information Model January 2008
Allowed values for this property are 'data',
'option', and 'all'.
</documentation>
</annotation>
</attribute>
<attribute name="status" type="ipfix:status"
use="required">
<annotation>
<documentation>
The status of the specification of this
Information Element. Allowed values are 'current',
'deprecated', and 'obsolete'.
</documentation>
</annotation>
</attribute>
<attribute name="group" type="string"
use="required">
<annotation>
<documentation>to be done ...</documentation>
</annotation>
</attribute>
</complexType>
</element>
</sequence>
</complexType>
<unique name="infoElementIdUnique">
<selector xpath="field"/>
<field xpath="elementId"/>
</unique>
</element>
</schema>
Quittek, et al. Standards Track [Page 169]
RFC 5102 IPFIX Information Model January 2008
Authors' Addresses
Juergen Quittek
NEC
Kurfuersten-Anlage 36
Heidelberg 69115
Germany
Phone: +49 6221 90511-15
EMail: quittek@nw.neclab.eu
URI: http://www.neclab.eu/
Stewart Bryant
Cisco Systems, Inc.
250, Longwater Ave., Green Park
Reading RG2 6GB
United Kingdom
EMail: stbryant@cisco.com
Benoit Claise
Cisco Systems, Inc.
De Kleetlaan 6a b1
Diegem 1831
Belgium
Phone: +32 2 704 5622
EMail: bclaise@cisco.com
Paul Aitken
Cisco Systems, Inc.
96 Commercial Quay
Edinburgh EH6 6LX
Scotland
Phone: +44 131 561 3616
EMail: paitken@cisco.com
Jeff Meyer
PayPal
2211 N. First St.
San Jose, CA 95131-2021
US
Phone: +1 408 976-9149
EMail: jemeyer@paypal.com
URI: http://www.paypal.com
Quittek, et al. Standards Track [Page 170]
RFC 5102 IPFIX Information Model January 2008
Full Copyright Statement
Copyright (C) The IETF Trust (2008).
This document is subject to the rights, licenses and restrictions
contained in BCP 78, and except as set forth therein, the authors
retain all their rights.
This document and the information contained herein are provided on an
"AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS
OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY, THE IETF TRUST AND
THE INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS
OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF
THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
Intellectual Property
The IETF takes no position regarding the validity or scope of any
Intellectual Property Rights or other rights that might be claimed to
pertain to the implementation or use of the technology described in
this document or the extent to which any license under such rights
might or might not be available; nor does it represent that it has
made any independent effort to identify any such rights. Information
on the procedures with respect to rights in RFC documents can be
found in BCP 78 and BCP 79.
Copies of IPR disclosures made to the IETF Secretariat and any
assurances of licenses to be made available, or the result of an
attempt made to obtain a general license or permission for the use of
such proprietary rights by implementers or users of this
specification can be obtained from the IETF on-line IPR repository at
http://www.ietf.org/ipr.
The IETF invites any interested party to bring to its attention any
copyrights, patents or patent applications, or other proprietary
rights that may cover technology that may be required to implement
this standard. Please address the information to the IETF at
ietf-ipr@ietf.org.
Quittek, et al. Standards Track [Page 171]
|