Internet-Draft BGP FlowSpec v2 April 2024
Hares, et al. Expires 30 October 2024 [Page]
Workgroup:
IDR Working Group
Internet-Draft:
draft-ietf-idr-flowspec-v2-04
Published:
Intended Status:
Standards Track
Expires:
Authors:
S. Hares
Hickory Hill Consulting
D. Eastlake
Futurewei Technologies
C. Yadlapalli
ATT
S. Maduscke
Verizon

BGP Flow Specification Version 2

Abstract

BGP flow specification version 1 (FSv1), defined in RFC 8955, RFC 8956, and RFC 9117 describes the distribution of traffic filter policy (traffic filters and actions) distributed via BGP. Multiple applications have used BGP FSv1 to distribute traffic filter policy. These applications include the following: mitigation of denial of service (DoS), enabling traffic filtering in BGP/MPLS VPNs, centralized traffic control of router firewall functions, and SFC traffic insertion.

During the deployment of BGP FSv1 a number of issues were detected due to lack of consistent TLV encoding for rules for flow specifications, lack of user ordering of filter rules and/or actions, and lack of clear definition of interaction with BGP peers not supporting FSv1. Version 2 of the BGP flow specification (FSv2) protocol addresses these features. In order to provide a clear demarcation between FSv1 and FSv2, a different NLRI encapsulates FSv2.

Status of This Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at https://datatracker.ietf.org/drafts/current/.

Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."

This Internet-Draft will expire on 30 October 2024.

Table of Contents

1. Introduction

Modern IP routers have the capability to forward traffic and to classify, shape, rate limit, filter, or redirect packets based on administratively defined policies. These traffic policy mechanisms allow the operator to define match rules that operate on multiple fields within header of an IP data packet. The traffic policy allows actions to be taken upon a match to be associated with each match rule. These rules can be more widely defined as “event-condition-action” (ECA) rules where the event is always the reception of a packet.

BGP ([RFC4271]) flow specification as defined by [RFC8955], [RFC8956], [RFC9117] specifies the distribution of traffic filter policy (traffic filters and actions) via BGP to a mesh of BGP peers (IBGP and EBGP peers). The traffic filter policy is applied when packets are received on a router with the flow specification function turned on. The flow specification protocol defined in [RFC8955], [RFC8956], and [RFC9117] will be called BGP flow specification version 1 (BGP FSv1) in this draft.

Some modern IP routers also include the abilities of firewalls which can match on a sequence of packet events based on administrative policy. These firewall capabilities allow for user ordering of match rules and user ordering of actions per match.

Multiple deployed applications currently use BGP FSv1 to distribute traffic filter policy. These applications include: 1) mitigation of Denial of Service (DoS), 2) traffic filtering in BGP/MPLS VPNS, and 3) centralized traffic control for networks utilizing SDN control of router firewall functions, 4) classifiers for insertion in an SFC, and 5) filters for SRv6 (segment routing v6).

During the deployment of BGP flow specification v1, the following issues were detected:

Networks currently cope with some of these issues by limiting the type of traffic filter policy sent in BGP. Current Networks do not have a good workaround/solution for applications that receive but do not understand FSv1 policies.

This document defines version 2 of the BGP flow specification protocol to address these shortcomings in BGP FSv1. Version 2 of BGP flow specification will be denoted as BGP FSv2.

BGP FSv1 as defined in [RFC8955], [RFC8956], and [RFC9117] specified 2 SAFIs (133, 134) to be used with IPv4 AFI (AFI = 1) and IPv6 AFI (AFI=2).

This document specifies 2 new SAFIs (TBD1, TBD2) for FSv2 to be used with 5 AFIs (1, 2, 6, 25, and 31) to allow user-ordered lists of traffic match filters for user-ordered traffic match actions encoded in Communities (Wide or Extended).

FSv1 and FSv2 use different AFI/SAFIs to send flow specification filters. Since BGP route selection is performed per AFI/SAFI, this approach can be termed “ships in the night” based on AFI/SAFI.

FSv1 is a critical component of deployed applications. Therefore, this specification defines how FSv2 will interact with BGP peers that support either FSv2, FSv1, FSv2 and FSv1,or neither of them. It is expected that a transition to FSv2 will occur over time as new applications require FSv2 extensibility and user-defined ordering for rules and actions or network operators tire of the restrictions of FSv1 such as error handling issues and restricted topologies.

Section 2 contains the definition of Flow specification, a short review of FSv1 and an overview of FSv2. Section 3 contains the encoding rules for FSv2 and user-based encoding sent via BGP. Section 4 describes how to validate FSv2 NLRI. Section 5 discusses how to order FSV2 rules. Section 6 covers combining FSv2 user-ordered match rules and FSv1 rules. Section 6 also discusses how to combine user-ordered actions, FSv1 actions, and default actions. Sections 7-10 address an alternate security mechanism, considerations for IANA, security in deployments, and scalability aspirations.

1.1. Definitions and Acronyms

  • AFI - Address Family Identifier

  • AS - Autonomous System

  • BGPSEC - secure BGP [RFC8205] updated by [RFC8206]

  • BGP Session ephemeral state - state which does not survive the loss of BGP peer session.

  • Configuration state - state which persist across a reboot of software module within a routing system or a reboot of a hardware routing device.

  • DDOs - Distributed Denial of Service.

  • Ephemeral state - state which does not survive the reboot of a software module, or a hardware reboot. Ephemeral state can be ephemeral configuration state or operational state.

  • FSv1 - Flow Specification version 1 [RFC8955] [RFC8956]

  • FSv2 - Flow Specification version 2 (this document)

  • NETCONF - The Network Configuration Protocol [RFC6241].

  • RESTCONF - The RESTCONF configuration Protocol [RFC8040]

  • RIB - Routing Information Base.

  • ROA - Route Origin Authentication [RFC6482]

  • RR - Route Reflector.

  • SAFI – Subsequent Address Family Identifier

1.2. RFC 2119 language

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 BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals as shown here.

2. Flow Specification

A BGP Flow Specification is an n-tuple containing one or more match criteria that can be applied to IP traffic, traffic encapsulated in IP traffic or traffic associated with IP traffic. The following are examples of such traffic: IP packet or an IP packet inside a L2 packet (Ethernet), an MPLS packet, and SFC flow.

A given Flow Specification NLRI may be associated with a set of path attributes depending on the particular application, and attributes within that set may or may not include reachability information (e.g., NEXT_HOP). Extended Community or Wide Community attributes (well-known or AS-specific) MAY be used to encode a set of pre-determined actions.

A particular application is identified by a specific AFI/SAFI (Address Family Identifier/Subsequent Address Family Identifier) and corresponds to a distinct set of RIBs. Those RIBs should be treated independently of each other in order to assure noninterference between distinct applications.

BGP processing treats the NLRI as a key to entries in AFI/SAFI BGP databases. Entries that are placed in the Loc-RIB are then associated with a given set of semantics which are application dependent. Standard BGP mechanisms such as update filtering by NLRI or by attributes such as AS_PATH or large communities apply to the BGP Flow Specification defined NLRI-types.

Network operators can control the propagation of BGP routes by enabling or disabling the exchange of routes for a particular AFI/SAFI pair on a particular peering session. As such, the Flow Specification may be distributed to only a portion of the BGP infrastructure.

2.1. Flow Specification v1 (FSv1) Overview

The FSv1 NLRI defined in [RFC8955] and [RFC8956] include 13 match conditions encoded for the following AFI/SAFIs:

If one considers the reception of the packet as an event, then BGP FSv1 describes a set of Event-MatchCondition-Action (ECA) policies where:

The flow specification conditions and actions combine to make up FSv1 specification rules. Each FSv1 NLRI must have a type 1 component (destination prefix). Extended Communities with FSv1 actions can be attached to a single NLRI or multiple NLRIs in a BGP message

Within an AFI/SAFI pair, FSv1 rules are ordered based on the components in the packet (types 1-13) ordered from left-most to right-most and within the component types by value of the component. Rules are inserted in the rule list by component-based order where an FSv1 rule with existing component type has higher precedence than one missing a specific component type,

Since FSv1 specifications ([RFC8955], [RFC8956], and [RFC9117]) specify that the FSv1 NLRI MUST have a destination prefix (as component type 1) embedded in the flow specification, the FSv1 rules with destination components are ordered by IP Prefix comparison rules for IPv4 ([RFC8955]) and IPv6 ([RFC8956]). [RFC8955] specifies that more specific prefixes (aka longest match) have higher precedence than that of less specific prefixes and that for prefixes of the same length the lower IP number is selected (lowest IP value). [RFC8955] specifies that if the offsets within component 1 are the same, then the longest match and lowest IP comparison rules from [RFC8955] apply. If the offsets are different, then the lower offset has precedence.

These rules provide a set of FSv1 rules ordered by IP Destination Prefix by longest match and lowest IP address. [RFC8955] also states that the requirement for a destination prefix component “MAY be relaxed by explicit configuration” Since the rule insertions are based on comparing component types between two rules in order, this means the rules without destination prefixes are inserted after all rules which contain destination prefix component.

The actions specified in FSv1 are:

Figure 1 shows a diagram of the FSv1 logical data structures with 5 rules. If FSv1 rules have destination prefix components (type=1) and FSv1 rule 5 does not have a destination prefix, then FSv1 rule 5 will be inserted in the policy after rules 1-4.


     +--------------------------------------+
     | Flow Specification (FS)              |
     |  Policy                              |
     +--------------------------------------+
         ^               ^              ^
         |               |              |
         |               |              |
+--------^----+  +-------^-------+     +-------------+
|   FS Rule 1 |  |   FS Rule 2   | ... |  FS rule 5  |
+-------------+  +---------------+     +-------------+
                    :          :
                    :          :
                 ...:          :........
                 :                     :
       +---------V---------+      +----V-------------+
       |  Rule Condition   |      |   Rule Action    |
       |  in BGP NLRIs     |      | in BGP extended  |
       | AFIs: 1 and 2     |      | Communities      |
       | SAFI 133, 134     |      |                  |
       +-------------------+      +------------------+
           :     :    :                 :      :    :
      .....:     .    :.....       .....:      .    :.....
      :          :         :       :           :         :
 +----V---+  +---V----+ +--V---+ +-V------+ +--V-----++--V---+
 |  Match |  | match  | |match | | Action | | action ||action|
 |Operator|  |Variable| |Value | |Operator| |variable|| Value|
 |*1      |  |        | |      | |(subtype| |        ||      |
 +--------+  +--------+ +------+ +--------+ +--------++------+

   *1 match operator may be complex.

   Figure 2-1: BGP Flow Specification v1 Policy

2.2. Flow Specification v2 (FSv2) Overview

Flow Specification v2 allows the user to order the flow specification rules and the actions associated with a rule. Each FSv2 rule may have one or more match conditions and one or more associated actions.

This FSv2 specification supports the components and actions for the following:

The FSv2 specification for tunnel traffic is outside the scope of this specification. The FSv1 specification for tunneled traffic is in [I-D.ietf-idr-flowspec-nvo3].

FSv2 operates in the ships-in-the night model with FSv1 so network operators can manipulate which the distribution of FSv2 and FSv1 using configuration parameters. Since the lack of deterministic ordering was an FSv1 problem, this specification provides rules and protocol features to keep filters in a deterministic order between FSv1 and FSv2.

The basic principles regarding ordering of flow specification filter rules are:

Figure 2-2 provides a logical diagram of the FSv2 structure


       +--------------------------------+
       |          Rule Group            |
       +--------------------------------+
         ^          ^                  ^
         |          |---------         |
         |                   |         ------
         |                   |               |
+--------^-------+   +-------^-----+     +---^-----+
|      Rule1     |   |     Rule2   | ... |  Rule-n |
+----------------+   +-------------+     +---------+
                      :  :   :    :
    :.................:  :   :    :
    :          |.........:   :    :
 +--V--+    +--V--+          :    :
 | name|    |order| .........:    :.....
 +-----+    +-----+ :                  :
                    :                  :
   +----------------V----+  +-----V----------------+
   |Rule Match condition |  | Rule Action          |
   +---------------------+  +----------------------+
    :      :     :    :       :      :   :   :   |
 +--V--+   :     :    :    +--V---+  :   :   :   V
 | Rule|   :     :    :    |action|  :   :   :  +-----------+
 | name|   :     :    :    |order |  :   :   :  |action name|
 +-----+   :     :    :    +------+  :   :   :  +-----------+
           :     :    :              :   :   :.............
           :     :    :              :   :                :
      .....:     .    :.....       ..:   :......          :
      :          :         :       :           :          :
 +----V---+  +---V----+ +--V---+ +-V------+ +--V-----+ +--V---+
 |  Match |  | match  | |match | | Action | | action | |action|
 |Operator|  |variable| |Value | |Operator| |Variable| | Value|
 +--------+  +--------+ +------+ +--------+ +--------+ +------+

   Figure 2-2: BGP FSv2 Data storage

3. FSv2 Filters and Actions

The BGP FSv2 uses an NRLI with the format for AFIs for IPv4 (AFI = 1), IPv6 (AFI = 2), L2 (AFI = 6), L2VPN (AFI=25), and SFC (AFI=31) with two following SAFIs to support transmission of the flow specification which supports user ordering of traffic filters and actions for IP traffic and IP VPN traffic.

This NLRI information is encoded using MP_REACH_NLRI and MP_UNREACH_NLRI attributes defined in [RFC4760]. When advertising FSv2 NLRI, the length of the Next-Hop Network Address MUST be set to 0. Upon reception, the Network Address in the Next-Hop field MUST be ignored.

Implementations wishing to exchange flow specification rules MUST use BGP's Capability Advertisement facility to exchange the Multiprotocol Extension Capability Code (Code 1) as defined in [RFC4760], and indicate a capability for FSv1, FSv2 (Code TBD3), or both.

The AFI/SAFI NLRI for BGP Flow Specification version 2 (FSv2) has the format:

 +-------------------------------+
 |length (2 octets)              |
 +-------------------------------+
 | Sub-TLVs (variable)           |
 | +===========================+ |
 | | order (4 octets)          | |
 | +---------------------------+ |
 | | identifier (4 octets)     | |
 | +---------------------------+ |
 | | type (2 octets)           | |
 | +---------------------------+ |
 | | length-Subtlv (2 octets)  | |
 | +---------------------------+ |
 | | value (variable)          | |
 | +===========================+ |
 +-------------------------------+


    Figure 3-1: FSv2 format

where:

3.1. Filters

3.1.1. IP header SubTLV (type=1)

The format of the IP header TLV value field is shown in figure 3-2. The IP header for the VPN case is specified in section 3.5.

    +-------------------------------+
    | +--------------------------+  |
    | | (subTLVs)+               |  |
    | +==========================+  |
    +-------------------------------+

      Figure 3-2 - IP Header TLV

Where: Each SubTLV has the format:

    +-------------------------------+
    |  SubTLV type (1 octet)        |
    +-------------------------------+
    |  length (1 octet)             |
    + ------------------------------+
    |  value (variable)             |
    +-------------------------------+
     Figure 3-3 – IP header SubTLV format

Where:

Many of the components use the operators [numeric_op] and [bitmask_op] defined in [RFC8955]

The list of valid SubTLV types appears in Table 2.

Table 2 IP SubTLV Types for IP Filters
SubTLV
-type   Definition
======  ============
   1 -  IP Destination prefix
   2 -  IP Source prefix
   3 –  IPv4 Protocol / IPv6 Upper Layer Protocol
   4 –  Port
   5 –  Destination Port
   6 –  Source Port
   7 –  ICMPv4 type / ICMPv6 type
   8 –  ICMPv4 code / ICPv6 code
   9 –  TCP Flags
  10 –  Packet length
  11 –  DSCP (Differentiated Services Code Point)
  12 –  Fragment
  13 –  Flow Label
  14 -  TTL
  15-63 unassigned (IP flow)
 Table 3 Non-IP Types for IP Filters
SubTLV
-type     Definition
======    ============
  64 –    Parts of SID
  65 -    MPLS Match 1: Label in Label stack
  66 -    MPLS Match 2: EXP bits in top Label
  67-249  unassigned (reserved for now)
  250-    Filter Error handling
  251-255 Reserved

Ordering within the TLV in FSv2: The transmission of SubTLVs within a flow specification rule MUST be sent ascending order by SubTLV type. If the SubTLV types are the same, then the value fields are compared using mechanisms defined in [RFC8955] and [RFC8956] and MUST be in ascending order. NLRIs having TLVs which do not follow the above ordering rules MUST be considered as malformed by a BGP FSv2 propagator. This rule prevents any ambiguities that arise from the multiple copies of the same NLRI from multiple BGP FSv2 propagators. A BGP implementation SHOULD treat such malformed NLRIs as "Treat-as-withdraw" [RFC7606].

See [RFC8955], [RFC8956], and [I-D.ietf-idr-flowspec-srv6]. for specific details.

3.1.1.1. IP Destination Prefix (type = 1)

IPv4 Name: IP Destination Prefix (reference: [RFC8955])

IPv6 Name: IPv6 Destination Prefix (reference: [RFC8956])

IPv4 length: Prefix length in bits

IPv4 value: IPv4 Prefix (variable length)

IPv6 length: length of value

IPv6 value: [offset (1 octet)] [pattern (variable)] [padding(variable)]

If IPv6 length = 0 and offset = 0, then component matches every address. Otherwise, length must be offset "less than" length "less than" 129 or component is malformed.

3.1.1.2. IP Source Prefix (type = 2)

IPv4 Name: IP Source Prefix (reference: [RFC8955])

IPv6 Name: IPv6 Source Prefix (reference: [RFC8956])

IPv4 length: Prefix length in bits

IPv4 value: Source IPv4 Prefix (variable length)

IPv6 length: length of value

IPv6 value: [offset (1 octet)] [pattern (variable)][padding(variable)]

If IPv6 length = 0 and offset = 0, then component matches every address. Otherwise, length must be offset < length < 129 or component is malformed.

3.1.1.3. IP Protocol (type = 3)

IPv4 Name: IP Protocol IP Source Prefix (reference: [RFC8955])

IPv6 Name: IPv6 Upper-Layer Protocol: (reference: [RFC8956])

IPv4 length: variable

IPv4 value: [numeric_op, value]+

IPv6 length: variable

IPv6 value: [numeric_op, value}+

where the value following each numeric_op is a single octet.

3.1.1.4. Port (type = 4)

IPv4/IPv6 Name: Port (reference: [RFC8955]), [RFC8956])

Filter defines: a set of port values to match either destination port or source port.

IPv4 length: variable

IPv4 value: [numeric_op, value]+

IPv6 length: variable

IPv6 value: [numeric_op, value]+

where the value following each numeric_op is a single octet.

Note-1: (from FSV1) In the presence of the port component (destination or source port), only a TCP (port 6) or UDP (port 17) packet can match the entire flow specification. If the packet is fragmented and this is not the first fragment, then the system may not be able to find the header. At this point, the FSv2 filter may fail to detect the correct flow. Similarly, if other IP options or the encapsulating security payload (ESP) is present, then the node may not be able to describe the transport header and the FSv2 filter may fail to detect the flow.

The restriction in note-1 comes from the inheritance of the FSv1 filter component for port. If better resolution is desired, a new FSv2 filter should be defined.

Note-2: FSv2 component only matches the first upper layer protocol value.

3.1.1.5. Destination Port (type = 5)

IPv4/IPv6 Name: Destination Port (reference: [RFC8955]), [RFC8956])

Filter defines: a list of match filters for destination port for TCP or UDP within a received packet

Length: variable

Component Value format: [numeric_op, value]+

3.1.1.6. Source Port (type = 6)

IPv4/IPv6 Name: Source Port (reference: [RFC8955]), [RFC8956])

Filter defines: a list of match filters for source port for TCP or UDP within a received packet

IPv4/IPv6 length: variable

IPv4/Ipv6 value: [numeric_op, value]+

3.1.1.7. ICMP Type (type = 7)

IPv4: ICMP Type (reference: [RFC8955])

Filter defines: Defines: a list of match criteria for ICMPv4 type

IPv6: ICMPv6 Type (reference: [RFC8956])

Filter defines: a list of match criteria for ICMPv6 type.

IPv4/IPv6 length: variable

IPv4/IPv6 value: [numeric_op, value]+

3.1.1.8. ICMP Code (type = 8)

IPv4: ICMP Type (reference: [RFC8955])

Filter defines: a list of match criteria for ICMPv4 code.

IPv6: ICMPv6 Type (reference: [RFC8956])

Filter defines: a list of match criteria for ICMPv6 code.

IPv4/IPv6 length: variable

IPv4/IPv6 value: [numeric_op, value]+

3.1.1.9. TCP Flags (type = 9)

IPv4/IPv6: TCP Flags Code (reference: [RFC8955])

Filter defines: a list of match criteria for TCP Control bits

IPv4/IPv6 length: variable

IPv4/IPv6 value: [bitmask_op, value]+

Note: a 2 octets bitmask match is always used for TCP-Flags

3.1.1.10. Packet length (type = 10 (0x0A))

IPv4/IPv6: Packet Length (reference: [RFC8955], [RFC8956])

Filter defines: a list of match criteria for length of packet (excluding L2 header but including IP header).

IPv4/IPv6 length: variable

IPv4/IPv6 value: [numeric_op, value]+

Note:[RFC8955] uses either 1 or 2 octet values.

3.1.1.11. DSCP (Differentiaed Services Code Point)(type = 11 (0x0B))

IPv4/IPv6: DSCP Code (reference: [RFC8955], [RFC8956])

Filter defines: a list of match criteria for DSCP code values to match the 6-bit DSCP field.

IPv4/IPv6 length: variable

IPv4/IPv6 value: [numeric_op, value]+

Note: This component uses the Numeric Operator (numeric_op) described in [RFC8955] in section 4.2.1.1. Type 11 component values MUST be encoded as single octet (numeric_op len=00).

The six least significant bits contain the DSCP value. All other bits SHOULD be treated as 0.

3.1.1.12. Fragment (type = 12 (0x0C))

IPv4/IPv6: Fragment (reference: [RFC8955], [RFC8956])

Filter defines: a list of match criteria for specific IP fragments.

Length: variable

Component Value format: [bitmask_op, value]+

Bitmask values are:

      0    1   2   3   4   5   6  7
    +---+---+---+---+---+---+---+---+
    | 0 | 0 | 0 | 0 |LF |FF |IsF| DF|
    +---+---+---+---+---+---+---+---+
                 Figure 3-4

Where:

  • DF (don’t fragment): match If IP header flags bit 1 (DF) is 1.

  • IsF(is a fragment other than first: match if IP header fragment offset is not 0.

  • FF (First Fragment): Match if [RFC0791] IP Header Fragment offset is zero and Flags Bit-2 (MF) is 1.

  • LF (last Fragment): Match if [RFC7091] IP header Fragment is not 0 And Flags bit-2 (MF) is 0

  • 0: MUST be sent in NLRI encoding as 0, and MUST be ignored during reception.

3.1.1.13. Flow Label(type = 13 (0xOD))

IPv4/IPv6: Fragment (reference: [RFC8956])

Filter defines: a list of match criteria for 20-bit Flow Label in the IPv6 header field.

Length: variable

Component Value format: [numeric_op, value]+

3.1.1.14. TTL (type=14 (0x0E))

TTL: Defines matches for 8-bit TTL field in IP header

Encoding: <[numeric_op, value]+>

where: value is a 1 octet value for TTL.

ordering: by full value of number_op concatenated with value

conflict: none

reference: draft-bergeon-flowspec-ttl-match-00.txt

3.1.1.15. Parts of SID (type = 64 (0x40))

IPv6: Service Identifier Matches (reference: [I-D.ietf-idr-flowspec-srv6]

Filter defines: a list of match bit match criteria for some combinations of the LOC (location), FUNCT (function) and ARG (arguments) fields in the SID or or whole SID.

Length: variable

Component Value format: [type, LOC-Len, FUNCT-Len, ARG-Len, [op, value]+]

where:

  • type (1 octet): This indicates the new component type (TBD1, which is to be assigned by IANA).

  • LOC-Len (1 octet): This indicates the length in bits of LOC in SID.

  • FUNCT-Len (1 octet): This indicates the length in bits of FUNCT in SID.

  • ARG-Len (1 octet): This indicates the length in bits of ARG in SID.

  • [op, value]+: This contains a list of {operator, value} pairs that are used to match some parts of SID.

The total of three lengths (i.e., LOC length + FUNCT length + ARG length) MUST NOT be greater than 128. If it is greater than 128, an error occurs and it is treated as a withdrawal [RFC7606] and [RFC4760].

The operator (op) byte is encoded as:

      0   1   2   3   4   5   6   7
    +---+---+---+---+---+---+---+---+
    | e | a | field type|lt |gt |eq |
    +---+---+---+---+---+---+---+---+
            Figure 3-5

where:

  • where the behavior of each operator bit has clear similarity with that of [RFC8955]'s Numeric Operator field.

  • e (end-of-list bit): Set in the last {op, value} pair in the sequence.

  • a - AND bit: If unset, the previous term is logically ORed with the current one. If set, the operation is a logical AND. It should be unset in the first operator byte of a sequence. The AND operator has higher priority than OR for the purposes of evaluating logical expressions.

  • field type:

    • 000: SID's LOC

    • 001: SID's FUNCT

    • 010: SID's ARG

    • 011: SID's LOC:FUNCT (the concatenation of the LOC and FUNCTION fields)

    • 100: SID's FUNCT:ARG (the concatenation of the FUNCTION and ARG fields)

    • 101: SID's LOC:FUNCT:ARG (the concatenation of the FUNCTION and ARG fields)

  • Note: For an unknown field type, Error Handling is to "treat as withdrawal" [RFC7606] and [RFC4760].

  • lt: less than comparison between data' and value'.

  • gt: greater than comparison between data' and value'.

  • eq: equality between data' and value'.

The data' and value' used in lt, gt and eq are indicated by the field type in an operator and the value field following the operator.

The length of the value field depends on the field type and is the length of the SID parts being matched (see Table 3, Figure 3-6) in bytes, rounded up if that length is not a multiple of 8.

         Table 3 - SID Parts fields

       +-----------------------+------------------------------+
       | Field Type            | Value                        |
       +=======================+==============================+
       | SID's LOC             | value of LOC bits            |
       +-----------------------+------------------------------+
       | SID's FUNCT           | value of FUNCT bits          |
       +-----------------------+------------------------------+
       | SID's ARG             | value of ARG bits            |
       +-----------------------+------------------------------+
       | SID's LOC:FUNCT       | value of LOC:FUNCT bits      |
       +-----------------------+------------------------------+
       | SID's FUNCT:ARG       | value of FUNCT:ARG bits      |
       +-----------------------+------------------------------+
       | SID's LOC:FUNCT:ARG   | value of LOC:FUNCT:ARG bits  |
       +-----------------------+------------------------------+


        ------------------ SID,  128 bits ----------------
       /                                                  \
      +-----------+-----------+-----------+----------------+
      |    LOC    |   FUNCT   |    ARG    |      ...       |
      +-----------+-----------+-----------+----------------+
       \         / \         / \         / \              /
          j bits     k bits       m bits    128-j-k-m bits
       \                     /
         LOC:FUNCT, j+k bits
                   \                     /
                     FUNCT:ARG, k+m bits
       \                                 /
         -- LOC:FUNCT:ARG, j+k+m bits –

                              Figure 3-6

3.1.1.16. MPLS Label Match1 (type=65, 0x41)
Type MPLS Label Match 1 (0x41)
Function: This match1 applies to MPLS Label field on the label stack.
reference: [I-D.ietf-idr-flowspec-mpls-match]
Encoding: <type(1 octet), length(1 octet), [operator,value]+>.
It contains a set of {operator, value} pairs that are used for the matching filter.

The operator byte is encoded as:

          0   1   2   3   4   5   6   7
    +---+---+---+---+---+---+---+---+
    | e | a | i |  pos  |   Resv    |
    +---+---+---+---+---+---+---+---+
                 Figure 3-7

where:

e - end of list bit:
Set in the last {op, value} pair in the list.
a - AND bit:
If unset, the previous term is logically ORed with the current one. If set, the operation is a logical AND. It should be unset in the first operator byte of a sequence. The AND operator has higher priority than OR for the purposes of evaluating logical expressions.
i – before bit:
If unset, apply matching filter before MPLS label data plane action; if set, apply matching filter after MPLS label data plane action.
pos – the label position indication bits:

whose meaning for various values is shown below:

00:any position on the label stack
- the presented label value is used to match any label on the label stack. When applying it, at least one label on the stack MUST match the value
01:top label indication-
the presented label value MUST be used to match the top label on the label stack.
10: bottom label indication-
the presented label value MUST match the bottom label on the label stack. When it is clear, the present label value can match to any label on the label stack
11: reserved value -
- This value is reserved and MUST not be sent in the packet.

The value field is encoded as:

                             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                          |
    +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
                     Figure 3-8
Reference:
3.1.1.17. MPLS Label Match 2: Experimental bits match on top label (Type=66 (0x42))
Type (16) MPLS Label Match 2: EXP bits
Function: MPLS Match2 applies to MPLS Label experiment bits (EXP) on the top label in the label stack.
reference: [I-D.ietf-idr-flowspec-mpls-match]

Encoding: <type (1 octet), [op, value]+>

[op,value] - Defines a list of {operation, value} pairs used to match 3-bit exp field on the top label of packets [RFC3032].
Values are encoded using a single byte, where the five most significant bits are zero and the three least significant bits contain the exp value.
3.1.1.18. Filter Error handling (Type=250 (0xFA)
Type Filter Error handling(0xFA)
Function: This function suggests additional for unknown types and missing fields.
reference: none
Encoding: <type(1 octet), length(1 octet), T-Err (1 octet), (M-Err (1 octet)
It contains a set of {operator, value} pairs that are used for the matching filter.

T-Err - specifies handling of unknown type. The values for this type are:

Disable AFI/SAFI
Treat as withdrawl
Ignore MP)REACH_NLRI attribute
Ignore filter component (Sub-TLV)
M-Error - specifies the handling of a missing field with values of: (TBD).
          0   1   2   3   4   5   6   7   8       9      10  11  12  13  14  15
    +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+
    |            T-Err              |  M-error                      |
    +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+
                 Figure 3-9

3.1.2. L2 Traffic Rules (type=2

The format of the L2 header TLV value field is shown in Figure 3-22. The AFI/SAFI field includes the AFI (2 octets), SAFI (1 octet).

       +-------------------------------+
       | +--------------------------+  |
       | | AFI/SAFI field (3)       |  |
       | +--------------------------+  |
       | | L3 AFI (2)               |  |
       | +--------------------------+  |
       | | L2 filter length (2)     |  |
       | +--------------------------+  |
       | | (SubTLVs)+ (L2 then L3)  |  |
       | +--------------------------+  |
       +-------------------------------+
         Figure 3-10 -L2 Header TLV value

Where:

  • AFI/SAFI field has AFI is 6 (IEEE 802) and SAFI is TBD1.

  • L3 AFI is zero if the filter test only L2 fields, otherwise it is or 2 depending on whether the filter L3 tests after the L2 header are for IPv4 or IPv6.

  • L2 filter length is the length of the L2 SubTLVs in bytes. These are followed by the L3 SubTLVs is the L3 AFI field is non-zero.

Each L2 SubTLV has the format shown in Figure 3-23. (The L3 SubTLVs are as defined in Section 4.1.)

        Each SubTLV has the format:

    +-------------------------------+
    |  SubTLV type (1 octet)        |
    +-------------------------------+
    |  length (1 octet)             |
    + ------------------------------+
    |  value (variable)             |
    +-------------------------------+
             Figure 3-11

SubTLV type: A component type value defined in the “L2 Flow Specification Component Types” registry for L2 by [draft-ietf-idr-flowspec-l2vpn).

Where the SubTLVs have the following component types:

Component Types Table

Component
type      Description
=======   ==================
1          EtherType
2          Source MAC
3          Destination MAC
4          DSAP (destination service access point)
5          SSAP (source service access point)
6          control field in LLC
7          SNAP
8          VLAN ID
9          VPAN PCP
10         Inner VLAN ID
11         Inner VLAN PCP
12         VLAN DEI
13         VLAN DEI
14         Source MAC special bits
15         Destination MAC special bits

   Table 4 – L2 VPN components

See [I-D.ietf-idr-flowspec-l2vpn] for the details on the format and value fields for each component.

Value ordering: Ordering of L2 FSv2 rules will be by user-defined order of the rule. For FSv2 filters within the same rule, the ordering will be by component number and then by value within the component. See [I-D.ietf-idr-flowspec-l2vpn] for the ordering of the values within the component.

L2 VPN filtering using SAFI TBD2 is specified in section 3.6.

reference: [I-D.ietf-idr-flowspec-l2vpn]

3.1.3. SFC Traffic Rules (type=3)

The FSv2 filters allow for filtering of the SFC NLRI family of routes. The traffic NLRIs filtered are from SFC AFI/SAFI (AFI = 31, SAFI=9).

The FSv2 filters provide this filtering with SFC AFI (AFI=31) and SAFI for FSv2 filters (SAFI = TB1).

    +--------------------------------------+
    | +---------------------------------+  |
    | | Tunneled AFI/SAFI field         |  |
    | +---------------------------------+  |
    | |                                 |  |
    | | <subTLVs>+                      |  |
    | +---------------------------------+  |
    +--------------------------------------+

              Figure 3-12

Each SubTLV has the format:

    +-------------------------------+
    |  SubTLV type (1 octet)        |
    +-------------------------------+
    |  length (1 octet)             |
    + ------------------------------+
    |  value (variable)             |
    +-------------------------------+
     Figure 3-13 – Tunneled SubTLV format

The components listed are:

   1 = SFIR RD Type (types 1, 2, 3)
   2 = SFIR RD Value
   3 = SFIR Pool ID
   4 = SFIR MPLS context/label
   5 = SFPR SPI
   6 = SPF attribute fields

    Table 5 – SFC Filter types

Ordering is by: User-defined rule order, component number, and then value within component.

reference: [RFC9015], [TBD]

3.1.4. BGP/MPLS VPN IP Traffic Rules (type=5)

The format of the match filter for BGP/MPLS VPN IP traffic is very similar to the format for non-VPN IP traffic as defined in Section 3.1 except that the SAFI is TBD2 and the initial NLRI header has an 8-byte Route Distinguisher added to it as shown in Figure 3-26. The SubTLV format and filter components formats remain the same.

       +-------------------------------+
       | +--------------------------+  |
       | | AFI/SAFI field (3)       |  |
       | +--------------------------+  |
       | | Route Distinguisher (8)  |  |
       | +--------------------------+  |
       | | (subTLVs)+               |  |
       | +--------------------------+  |
       +-------------------------------+

         Figure 3-14: VPN IP Filter Header

3.1.5. BGP/MPLS VPN L2 Traffic Rules (type=6)

The format of the match filter for BGP/MPLS VPN IP traffic is very similar to the format for non-VPN L2 traffic as defined in Section 3.4 except that the SAFI is TBD2 and the initial NLRI header has an 8-byte Route Distinguisher added to it right after the AFI/SAFI as shown in Figure 3-27 The SubTLV format and filter components formats remain the same.


       +-------------------------------+
       | +--------------------------+  |
       | | AFI/SAFI field (3)       |  |
       | +--------------------------+  |
       | | Route Distinguisher (8)  |  |
       | +--------------------------+  |
       | | L3 AFI (2)               |  |
       | +--------------------------+  |
       | | L2 filter length (2)     |  |
       | +--------------------------+  |
       | | (subTLVs)+               |  |
       | +--------------------------+  |
       +-------------------------------+

         Figure 3-15: VPN L2 Filter Header

3.2. FSV2 Actions

The FSv2 actions may be sent in an Extended Community or a Wide Community. User ordering of FSv2 actions requires using Wide Communities.

The Extended Community encodes the Flow Specification actions in the Extended IPv4 Community format [RFC4360] or in the extended IPv6 Community format [RFC5701]. The Extended Community actions cannot be ordered by the user. The implementer and the network deploying these actions need to ensure that policy constraints these Extended Community actions appropriately. A new Extended Community (Action Chain Order) is defined below to provide a clear failure mode for FSv2 actions implementation that support this action.

Implementation for a basic DDOS should include FSv2 IP filters, Extended Community actions, and the new Action Chain Ordering (This grouping of FSv2 features will be denoted as FSv2 Basic IP DDOS).

Wide Community can support user ordering of actions, and the dependency between actions. Wide Communities allow for multiple types of formats by supporting a common header with type and an indication whether the type is transitive within ASes or Confederations. The only Type 1 defined by the [I-D.ietf-idr-wide-bgp-communities] or a new Type 2 Wide Community (this document). The Type 1 body is a general community header that contains 31 bits of a community (4 bytes), a source AS (4 octets), and a context AS, and TLVs.

This specification defines a type 2 format Wide Communities that is specific to Flow Specification Actions. For new implementations, this form is streamline for FSv2 actions. A Wide Community Type 1 format is provided to ease transition, but it may contain extra bytes unneeded by FSV2 actions.

This section first describes the following Information related to FSv2 Actions in Extended Communities:

Second this section describes the information regarding user-ordered FSv2 actions encoded in Wide Communities:

3.2.1. FSv2 Actions in Extended Community Formats

The Extended Community will support existing IPv4 from [RFC8955], and existing IPv6 actions from [RFC8956] and one additional feature for action chain ordering (ACO).

An action chain for FSv2 Extended Community actions is defined as a series of Extended Communities which are attached to a set of filters. The action chain ordering (ACO) action provides a set of flags that define what happens if failure occurs. One of the issues with FSv1 is the lack of a clear definition on what happens if multiple actions interact. The existance of the Action chain ordering action enforces that the actions will have a deterministic outcome during failures.

The AC-Failure types are:

  • 0x00 – default – stop on failure

  • 0x01 – continue on failure (best effort on actions)

  • 0x02 – conditional stop on failure (depends on AC-Failure-value/policy)

  • 0x03 – rollback do all or nothing (depends on AC-Failure-value/policy)

Editors note: The following options for encoding ACO exist.

Option 1:
redefine bits in Traffic Action subtype
Option 2:
create a new Extended Community
3.2.1.1. FSv2 Extended Community IPv4 Encoding

The Extended Community encodes the Flow Specification actions in the Extended Community format as generic transitive extended communities per [RFC4360] per [RFC8955], [RFC9117], and [RFC9184].

The format of the these actions can be:

Generic Transitive Extended Community (0x80):
where the Sub-Types are defined in the Generic Transitive Extended Community Sub-Types registry.
Generic Transitive Extended Community Part 2(0x81):
where the Sub-Types are defined in the Generic Transitive Extended Community Part 2 Sub-Types registry.
Transitive Four-Octet AS-Specific Extended Communit(0x82):
where the Sub-Types defined in the Generic Transitive Extended Community Part 3 Sub-Types registry.
Generic Transitive Extended Community Part 3 (0x83):
where the Sub-Types defined in the Transitive Opaque Extended Community Sub-Types" registry.

  IPV4 Extended Community Format

  0                   1                   2                   3
  0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |  Type high    |  Type low(*)  |                               |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+          Value (6 octets)     |
 |                                                               |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

                 Figure 3-16

                                Table 6

IPv4 Extended Communities (Type 0x80) 2 byte AS,
Value   Description                  Name  Reference
=====   =======================      ===== ==========
0x01    Flow Spec Action Chain       ACO   [This document]
0x06    Flow spec traffic-rate-byte  TRB   [RFC8955][This document]
0x07    Flow spec traffic-action     TAIS  [RFC8955][This document]
0x08    Flow spec rt-redirect        RDIP  [RFC8955][This document]
        AS-2 octet format
0x09    Flow spec traffic-remarking      TM    [RFC8955][this document]
0x0C    Flow Spec Traffic-           TRP   [RFC8955][this document]
         rate-packets
                                Table 7

IPv4 Extended Communities FSv2 action (Type 0x81)
Value   Description                    Name  Reference
=====   =======================        ===== ==========
0x08    Flow spec rt-redirect          RDIP  [RFC8955]
        IPv4 octet format                        [this document]

                                Table 8
IPv4 Extended Communities (Type 0x82)
Value   Description                  Name  Reference
=====   =======================      ====  ==========
0x08    Flow spec rt-redirect        RDIP  [RFC8955]
        AS-4 octet format                      [this document]
3.2.1.2. IPv6 Extended Community Encoding
 IPv6 Extended Community format

  0                   1                   2                   3
  0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |  Type         |  Sub-type     |   Global Administrator        |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-|
 |         Global Administrator (cont.)                          |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |         Global Administrator (cont.)                          |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |         Global Administrator (cont.)                          |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 | Global Administrator (cont.)  |   Local Administrator         |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

               figure 3-17

The 20 octets of value are given in the following format:

Global Administrator - IPv6 Address setting extended community
Local Administrator - 2 bytes of Community for action.


                 Table 9

IPv6 Extended Communities (Type 1)
Value   Description                  Name   Reference
=====   =======================      =====  ==========
0x01    Flow Spec Action Chain       ACO    [This document]
0x0C    Flow Spec redirect-v6-flag   RD6F   [ID-redirect-IP]
0x0D    Flow Spec rt-redirect        RD6    [RFC8956]
        IPv6 format
3.2.1.3. Action Chain operation (ACO) Extended Community (Type 1 0x01)

SubTLV: 0x01

Length: 6 bytes

Value:

  • AC-failure-type – 1 octet (action code)

  • AC-dependency-flags - 1 octet (flags)

  • AC-failure-value - 4 octet of failure action

Actions may succeed or fail and an Action chain must deal with it. The default value stored for an action chain that does not have this action chain is “stop on failure”.

where:

  • AC-Failure types are:

    • 0x00 – default – stop on failure

    • 0x01 – continue on failure (best effort on actions)

    • 0x02 – conditional stop on failure – depending on AC-Failure-value

    • 0x03 – rollback – do all or nothing - depending in AC-Failure-value

  • AC-dependency-flags - flags to indicate whether this action is part of a sequence of actions (Editor: More discussion needed).

  • AC-Failure values: TBD

Interactions with other actions: Interactions with all other Actions

Ordering within Action type: By AC-Failure type

3.2.2. FSv2 Actions encoded in Wide Community Encoding

The user ordered FSv2 Actions require the use of Wide Communities [I-D.ietf-idr-wide-bgp-communities]. This document defines a new Community Type (FSV2 actions) and an way to use Type 1 for FSv2 actions.

3.2.2.1. Wide Community Header

  Wide Community common header

   0                   1                   2                   3
 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|             Type              |    Flags  |T|C|   Reserved    |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|            Length             |    Type 1 or Type 2 format
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+............................

                          figure 3-18
where:

Type = the type of community (Type 1 or Type 2)
Flag = include an octet of bits with only two
       bit that can be set
           T = 1 - Transitive across AS boundaries
           T = 0 - Non-Transitive across AS boundaries
           C = 1 - Transitive across Confederation boundaries
           C = 0 - Non-Transitive across Confederation boundaries

3.2.2.2. FSv2 Wide Community Type 2

The Wide Communities Type 2 contains the following a common header and FSv2 Action TLVS. The FSv2 Action TLVs utilized in both the Wide Communities Type 1 and Type 2 Encoding.


Common header with Type 2 specified

 0                   1                   2                   3
 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|             Type=2           |    Flags  |C|T|   Reserved    |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|            Length             |<sequence of FSv2-Action-TLV>+ |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

                       Figure 3-19

3.2.2.3. FSv2 Wide Community Type 1 Encoding
Type 1 Wide Community

 0                   1                   2                   3
 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|I| user Action order           | dependency chain ID           |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                        Source AS Number                       |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                       Context AS Number                       |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                                                               |
|                       <action-subTLVs>                  |
|                                                               |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

                       Figure 3-20
 action order -    2 octets with user ordering within the list
                   1 octet has high bit set to zero (0).
                                   This allows values
                   with values from  1 (0x01) to 32752 (0xFF00)
                   ascending ordering (1 (first) to 65280.

 D-chain (Dependency chain) -  1 octet with dependency chain ID
 D-chain order (D-chain order) -  1 octet with order within chain

 Action Sub-TLVs - variable length format
                   see definitions within this document.

where FSv2-Action SubTLV are defined in the section below.

3.2.2.4. Action SubTLVs
3.2.2.4.1. Action Chain operation (ACO) [Wide Community] (1, 0x01)

SubTLV: 0x01

Length: variable

Value:

  • AC-failure-type – byte that determines the action on failure

  • AC-failure-value – variable depending on AC-failure-type.

Actions may succeed or fail and an Action chain must deal with it. The default value stored for an action chain that does not have this action chain is “stop on failure”.

where:

  • AC-Failure types are:

    • 0x00 – default – stop on failure

    • 0x01 – continue on failure (best effort on actions)

    • 0x02 – conditional stop on failure – depending on AC-Failure-value

    • 0x03 – rollback – do all or nothing - depending in AC-Failure-value

  • AC-Failure values: TBD

Interactions with other actions: Interactions with all other Actions

Ordering within Action type: By AC-Failure type

3.2.2.4.2. Traffic Actions per interface set (TAIS) (2, 0x02)

SubTLV: 0x02

Length: 8 octets (6 in extended community)

Value field: [4-octet-AS] [GroupID 2-octet] [action 2-octet]

where:

  • Group-ID: identifier for group in 2 octets (14 lower bits)

    • Note: Extended Community format will have 2 bits for action.

  • Action: determines inbound or outbound action where:

    • Outbound(0x1): FSv2 rule MUST be applied in outbound Direction to interface set identified by Group-ID.

    • Inbound (0x2): FSv2 rule MUST be applied in inbound Direction to interface set identified by Group-ID.

Value ordering: AS, then Group ID, then Action bytes.

Conflict: with any bi-direction action such as

  1. traffic rate limited by bytes, or

  2. traffic rate limited by packets.

Reference: [I-D.ietf-idr-flowspec-interfaceset]

3.2.2.4.3. Traffic rate limited by bytes (TRB) (6, 0x06)

SubTLV:0x06

Length: 8 octets

Value field:[4-octet-AS] [float (4 bytes)]

where:

  • [4-octet-AS]:4 byte AS number

    • If FSv1 passes the lower 2 bytes of 4 byte AS number, use [TBD6] as higher 2 bytes to identify.

    • Open issue : TBD6 can be either be chosen to match the common 2-byte to 4-byte or a unique value. Feedback is needed from WG and authors.

  • Float: maximum byte rate in IEEE 32-bit floating point [IEEE.754.19895 format] in bytes per second.

    • A value of 0 should result in all traffic for the particular flow to be discarded.

    • On encoding the traffic-rate-packets MUST NOT be negative.

    • On decoding, negative values MUST BE treated as zero (discard all traffic).

Value ordering: AS then float value

Action Conflict: traffic-rate-packets

reference: [RFC8955]

3.2.2.4.4. Traffic Action (TA)(7, 0x07)

SubTLV: 0x07

Length: 1

Value field: [1-octet action]

where the traffic action values are:

  • 1 = Terminal flow specification action

  • 2 = Sample – enables sampling and logging

  • 3 = Terminal action + sample

Value ordering: By traffic action values

Conflicts/Interactions: duplication of packets also occurs in:

  • Redirect to IPv4 (action 0x08),

  • Redirect to IPv6 (action 0x0D (13)),

  • Redirect to SFC (action 0xOE (14))

  • Redirect to Indirection-ID (action 0xF (15)

3.2.2.4.5. Redirect to IPv4 (RDIPv4)(8,0x08)

SubTLV: 0x08

Length: 12 octets

Value field:

[4-byte-AS] [IPv4 address (4 octets] [ID (4 octets)] [Flag (1 octet)]

where:

  • 4-octet-AS – is a 4-byte AS in a Route Target

  • IPv4 address - is an IP Address in RT

  • ID – the 4-octet value set by user

  • Flag is 1 octet value with the following definitions:

    • 0 - reserved

    • 1 - copy and redirect copy

Value ordering: 4-octet AS, then IP address, then ID (lowest to highest) with:

  • No AS specified uses AS value of zero.

  • No IP specified uses IP value of zero.

  • No ID specified uses ID value of zero.

Conflicts/Interactions: Any redirection or traffic sampling found in:

  • Traffic Action (action 0x07),

  • Redirect to IPv6 (action 0x0D (13)),

  • Redirect to SFC (action 0xOE (14))

  • Redirect to Indirection-ID (action 0xF (15)

reference: [RFC8955], draft-ietf-idr-flowspec-ip-02.txt

3.2.2.4.6. Traffic marking (TM) (9, 0x09)

SubTLV: 0x09

Length: 1 octet

Value: DSCP field with the 2 left most bits zero

The DSCP field format is:

     0  1  2  3  4  5  6  7
   +--+--+--+--+--+--+--+--+
   |R |R |   DSCP bits     |
   +--+--+--+--+--+--+--+--+

        Figure 3-21

where:

  • R - reserved bits (set to zero to send, ignored upon reception and set to zero.

  • DSCP – 6 bits of DSCP values

Ordering within Value: Based on DSCP value

Conflicts: none

reference: [RFC8955]

3.2.2.4.7. Traffic rate limited by packets (TRP) (12, 0xC)

SubTLV:12 (0xC)

Length: 8

Value field: [4-octet-AS] [float (4 octet)]

Where:

  • 4-octet AS – is the AS setting this value

  • Float – specifies maximum rate in IEEE 32-bit format [IEEE.754.185] in packets per second.

    • A traffic rate of zero should result in all packets being discard.

    • On encoding the traffic-rate-packets MUST NOT be negative.

    • On decoding, negative values MUST BE treated as zero (discard all traffic).

Ordering within Value: Based on DSCP value

Conflicts: Traffic rate limited by bytes (0x06)

reference: [RFC8955]

3.2.2.4.8. Traffic redirect to IPv6 (RDIPv6) (13, 0xD)

SubTLV: 13 (0xD)

Length: 24 octets

Value field: [4-octet-as] [IPv6-address (16 octets)] [local administrator (2 octets] [Flag (1 octets)]

where:

  • 4-octet-AS – is the AS requesting action in 4-byte AS format,

  • IPv6-address – is the redirection IPv6 address

  • Local administrator – 2 bytes assigned by network administrator.

  • lag (1 octet) with the following definitions:

    • 0 - reserved

    • 1 - copy and redirect copy

Ordering within Value: AS, then IPv6, the flag (low to high)

Conflicts/Interactions: Any redirection or traffic sampling found in:

  • Traffic Action (action 0x07) ,

  • Redirect to IPv4 (action 0x08 (8)),

  • Redirect to SFC (action 0xOE (14))

  • Redirect to Indirection-ID (action 0xF (15)

3.2.2.4.9. Flow Specification Redirect to Indirection-ID (RDIID) (15, 0x0F)

SubTLV: 15 (0x0F)

  • note: current value is 0x00 for FSv1

Length: 6 octets

Value field:

[Flags (1 octet)] [ID-Type (1 octet)][Generalized-ID (4 octets)]

     Figure 3-22

where:

  • Flags: are defined as:

    • [S-ID]: sequence number for indirection IDs (3 bits).

      • Value of zero means sequence is not set and all other S-ID values should be ignored

    • [C] – copy packets matching this ID

  • ID-Type: type of indirection ID with following values:

    • 0 – localized ID

    • 1 – Node with SID/index in MPLS SR

    • 2 – Node with SID/label in MPLS SR

    • 3 – Node with Binding Segment ID with SID/Index

    • 4 – Node with Binding Segment ID with SID/Label

    • 5 - Tunnel ID

  • Generalized-ID (G-ID): indirection value

Value Ordering: first indirection ID, then Generalized ID

Action Value ordering: ID-Type by value (lowest to highest)

Conflicts/Interactions: Any redirection or traffic sampling found in:

  • Traffic Action (action 0x07),

  • Redirect to IPv4 (action 0x08 (8)),

  • Redirect to IPv6 (action 0x0D, (13)

  • Redirect to SFC (action 0xOE (14))

reference: [I-D.ietf-idr-flowspec-path-redirect]

3.2.2.4.10. Traffic insertion in SFC (TISFC)(33, 0x21)

SubTLV:33 (0x21)

  • Note: replace IANA 0xD FSv1 with FSv2 OxE.

Length: 6 octets

Value field: [SPI (3 octets)][SI (1 octet)][SFT (2 octet)]

where:

  • SPI – is the service path identifier

  • SI – is the service index

  • SFT – is the service function type.

Value ordering: SPI, then SI, then SFT (lowest to highest)

Conflicts/Interactions: Any redirection or traffic sampling found in:

  • Traffic Action (action 0x07) ,

  • Redirect to IPv4 (action 0x08 (8)),

  • Redirect to IPv6 (action 0xOD (13))

  • Redirect to Indirection-ID (action 0xF (15)

Reference: [RFC9015]

3.2.2.4.11. MPLS Label Action (MPLSLA)(34, 0x22)

Function: MPLS Label actions

SubTLV: 34 (0x22)

Length: 6 octets

Value:

  • [action (1 octet)

  • [order (1 octet)

  • [Label Stack Entry (4 octets)]

where Action:

+------+------------------------------------------------------------+
|Action| Function                                                   |
+------+------------------------------------------------------------+
|  0   | Push the MPLS tag                                          |
+------+------------------------------------------------------------+
|  1   | Pop the outermost MPLS tag in the packet                   |
+------+------------------------------------------------------------+
|  2   | Swap the MPLS tag with the outermost MPLS tag in the packet|
+------+------------------------------------------------------------+
| 3~15 | Reserved                                                   |
+------+------------------------------------------------------------+

                    Figure 3-23
  0                   1                   2                   3
  0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
 |                Label                  | Exp |S|       TTL     |
 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

              Figure 3-24 - Label Stack Entry

Action Value ordering: ID-Type, then value (lowest to highest)

Value Ordering: order, action, label, Exp

Conflicts/Interactions: Any redirection for IP before MPLS

  • Traffic Action (action 0x07),

  • Redirect to IPv4 (action 0x08 (8)),

  • Redirect to IPv6 (action 0x0D, (13)

  • Redirect to SFC (action 0xOE (14))

reference: [I-D.ietf-idr-bgp-flowspec-label]

3.2.2.4.12. VLAN action (VLAN) (35, 0x23)

Function: Rewrite inner or outer VLAN header

SubTLV: 35 (0x23)

Length: 6 octets

Value:

  • [Rewrite-actions (2 octets)]

  • [vlan-PCP-DE-1 (2 octets)]

  • [vlan-PCP-DE-2 [2 octets)]

where:

  • Rewrite-actions – is as follows:


     0   1   2   3   4   5   6   7   8   9   10  11  12  13  14  15
   +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+
   |PO1|PU1|SW1|RI1|RO1| Resv      |PO2|PU2|SW2|RI2|RO2| Resv      |
   +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+

                           Figure 3-25
  • PO1: Pop action. If the PO1 flag is one, it indicates the outermost VLAN should be removed.

  • PU1: Push action. If PU1 is one, it indicates VLAN ID1 will be added, the associated Priority Code Point (PCP and Drop Eligibility Indicator (DEI) are PCP1 and DE1.

  • SW1: Swap action. If the SW1 flag is one, it indicates the outer VLAN and inner VLAN should be swapped.

  • PO2: Pop action. If the PO2 flag is one, it indicates the outermost VLAN should be removed.

  • PU2: Push action. If PU2 is one, it indicates VLAN ID2 will be added, the associated PCP and DEI are PCP2 and DE2.

  • SW2: Swap action. If the SW2 flag is one, it indicates the outer VLAN and inner VLAN should be swapped.

  • RI1 and RI2: Rewrite inner VLAN action. If the RIx flag is one where "x" is "1" or "2"), it indicates the inner VLAN should be replaced by a new VLAN where the new VLAN is VLAN IDx and the associated PCP and DEI are PCPx and DEx. If the VLAN IDx is 0, the action is to only modify the PCP and DEI value of the inner VLAN.

  • RO1 and RO2: Rewrite outer VLAN action. If the ROx flag is one (where "x" is "1" or "2"), it indicates the outer VLAN should be replaced by a new VLAN where the new VLAN is VLAN IDx and the associated PCP and DEI are PCPx and DEx. If the VLAN IDx is 0, the action is to only modify the PCP and DEI value of the outer VLAN.

  • Resv: Reserved for future use. MUST be sent as zero and ignored on receipt.

Value ordering: rewrite-actions, VLAN1, VLAN2, PCP-DE1, PCP-DE2

Conflicts: TIPD Action

reference: [I-D.ietf-idr-flowspec-l2vpn]

3.2.2.4.13. TPID action (TPID) (36, 0x24)

Function: Replace Inner or outer TP

SubTLV: 36 (0x24)

Length: 6 octets

Value:

  • [Rewrite-actions (2 octets)]

  • [TP-ID-1 (2 octets)]

  • [TP-ID-2 (2 octets)]

Where: rewrite-actions are bitmask (2 octets) with 2 actions as follows:


        0                                           15
      +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+
      |TI|TO|                     Resv                |
      +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+

                Figure 3-26

TI: Mapping inner Tag Protocol (TP) ID (typically a VLAN) action. If the TI flag is one, it indicates the inner TP ID should be replaced by a new TP ID, the new TP ID is TP ID1.

TO: Mapping outer TP ID action. If the TO flag is one, it indicates the outer TP ID should be replaced by a new TP ID, the new TP ID is TP ID2.

Resv: Reserved for future use. MUST be sent as zero and ignored on receipt

Value Ordering: rewrite-actions, TP-ID-1, TP-ID-2

Conflicts: VLAN action

reference:[I-D.ietf-idr-flowspec-l2vpn]

3.2.2.5. Extended Community vs. Action SubTLV formats

The SubTLV format is used for the Wide communities and for the action subTLVs in the NLRI.


                        Table 10

Sub-TLV  Action Action SubTLV      Extended Community
type     Name   format             format
=======  =====  ===============    ====================
 1       ACO    type: 1 (0x01)      IPv4 type (0x01)
                length:variable     length: 6
                                                    [2-octet-AS]

 2       TAIS   type: 2 (0x02)      type: 0x0702 or 0x4702
                length:8            length: 6
                [4-octet-as]         [4-octet-AS]
                [group-3-octet]      [flags-group]
                [flags-1-octet]        (2 octets)

 3-5     reserved



Sub-TLV Action Action SubTLV      Extended Community
type    Name   format             format
======= =====  ===============    ====================
 6       TRB    type:6 (0x06)       type:8006
                length:8            length: 6 octets
                [4-byte-AS]          [2-byte-AS]
                [float (4 octets)]   [float (4 octets)]

 7       TA     type:7              type:8007
                length:1            length:6 octets
                flags: (1 octet)    flags (6 octets)


 8       RDIPv4 type:8              type:8008
                length: 12          length: 6 octets
                [4-byte-AS]          [AS-2-octets]
                [IPv4-address]       [IPv4 address]
                                    type:8108
                                    length: 6 octets
                                     [IPv4 address]
                                     [ID-2 octets]
                                    type:8208
                                    length: 6 octets
                                     [AS-4-octets]
                                     [ID-2-octets]

9       TM      type:9              type:8009
                length:1            length: 6 octets
                DSCP: 1 octet        DSCP: 1 octet

10-11           Unassigned

12      TRP     type:12 (0x0C)     type: 0x800C
                length: 8 octets   length: 6 octets
                [4-byte-AS]         [2-byte-AS]
                [float-4-octet]     [float-4-octet]

13      RDIPv6  type:13 (0x0D)     type:0x000D (IPv6)
                length:22          length: 18 octets
                [4-byte-AS]         [IPv6-address (16)]
                [IPv6-address (16)] [local-admin (2)]
                [local-admin (2)]


15      RDIID   type:15 (0x0F)      type: 0900 (FSv1)
                length: 6           length 6
                flags (1)            flags (1)
                ID-type (1)          ID type (1)
                G-ID (4 octets)      G-ID (4-octets)
             Table 11

Non-IP packet actions
Sub-TLV Action Action SubTLV      Extended Community
type    Name   format             format
======= =====  ===============    ====================

33      TISFC   type:33 (0x21)      type: 0xD (FSv1/FSv2)
                length:6            length:6
                SPI (3 octets)       SPI (3 octets)
                SI (1 octet)         SI (1 octet)
                SFT (2 octets)       SFT (2 octets)

34      MPLSLA  type:34 (0x10)       (TBD)
                length: 6
                                action: 1 octet
                                [push/pop]
                                order: 1 octet
                mpls label (4 octets)



35      VLAN    type:35 (0x22)      Type: (TBD)
                length:6            length:6
                [rewrite-action(2)]  [rewrite-actions (2)]
                [vlan-pcp-de-1 (2)]  [vlan-pcp-de-1 (2)]
                [vlan-pcp-de-2 (2)]      [vlan-pcp-de-2 (2)]

36      TPID    type:35 (0x23)      Type: (TBD)
                length:6            length:6
                [rewrite-action(2)] [rewrite-actions (2)]
                [TP-ID-1 (2)]       [TP-ID-1 (2)]
                [TP-ID-2 (2)]       [TP-ID-2 (2)]

4. Validation of FSv2 NLRI

The validation of FSv2 NLRI adheres to the combination of rules for general BGP FSv1 NLRI found in [RFC8955], [RFC8956], [RFC9117], and the specific additions made for SFC NLRI [RFC9015], and L2VPN NLRI [I-D.ietf-idr-flowspec-l2vpn].

To provide clarity, the full validation process for flow specification routes (FSv1 or FSv2) is described in this section rather than simply referring to the relevant portions of these RFCs. Validation only occurs after BGP UPDATE message reception and the FSv2 NLRI and the path attributes relating to FSv2 (Extended community and Wide Community) have been determined to be well-formed. Any MALFORMED FSv2 NRLI is handled as a “TREAT as WITHDRAW” [RFC7606].

4.1. Validation of FS NLRI (FSv1 or FSv2)

Flow specifications received from a BGP peer that are accepted in the respective Adj-RIB-In are used as input to the route selection process. Although the forwarding attributes of the two routes for tbe same prefix may be the same, BGP is still required to perform its path selection algorithm in order to select the correct set of attributes to advertise.

The first step of the BGP Route selection procedure (section 9.1.2 of [RFC4271] is to exclude from the selection procedure routes that are considered unfeasible. In the context of IP routing information, this is used to validate that the NEXT_HOP Attribute of a given route is resolvable.

The concept can be extended in the case of the Flow Specification NLRI to allow other validation procedures.

The FSv2 validation process validates the FSv2 NLRI with following unicast routes received over the same AFI (1 or 2) but different SAFIs:

The FSv2 validates L2 FSv2 NLRI with the following L2 routes received over the same AFI (25), but a different SAFI:

In the absence of explicit configuration, a Flow specification NLRI (FSv1 or FSv2) MUST be validated such that it is considered feasible if and only if all of the conditions are true:

However, part of rule a may be relaxed by explicit configuration, permitting Flow Specifications that include no destination prefix component. If such is the case, rules b and c are moot and MUST be disregarded.

By “originator” of a BGP route, we mean either the address of the originator in the ORIGINATOR_ID Attribute [RFC4456] or the source address of the BGP peer, if this path attribute is not present.

A BGP implementation MUST enforce that the AS in the left-most position of the AS_PATH attribute of a Flow Specification Route (FSv1 or FSv2) received via the Exterior Border Gateway Protocol (eBGP) matches the AS in the left-most position of the AS_PATH attribute of the best-match unicast route for the destination prefix embedded in the Flow Specification (FSv1 or FSv2) NLRI.

The best-match unicast route may change over time independently of the Flow Specification NLRI (FSv1 or FSv2). Therefore, a revalidation of the Flow Specification MUST be performed whenever unicast routes change. Revalidation is defined as retesting rules a to c as described above.

4.2. Validation of Flow Specification Actions

Flow Specifications may be mapped to actions using Extended Communities or a Wide Communities. The FSv2 actions in Extended Communities and Wide communities can be associated with large number of NLRIs.

The ordering of precedence for these actions in the case when the user-defined order is the same follows the precedence of the FSv2 NLRI action TLV values (lowest to highest). User-defined order is the same when the order value for action is the same. All Extended Community actions MUST be translated to the user-defined order data format for internal comparison. By default, all Extended Community actions SHOULD be translated to a single value.

Actions may conflict, duplicate, or complement other actions. An example of conflict is the packet rate limiting by byte and by packet. An example of a duplicate is the request to copy or sample a packet under one of the redirect functions (RDIPv4, RDIPv6, RDIID, ) Each FSv2 actions in this document defines the potential conflicts or duplications. Specifications for new FSv2 actions outside of this specification MUST specify interactions or conflicts with any FSv2 actions (that appear in this specification or subsequent specifications).

Well-formed syntactically correct actions should be linked to a filtering rule in the order the actions should be taken. If one action in the ordered list fails, the default procedure is for the action process for this rule to stop and flag the error via system management. By explicit configuration, the action processing may continue after errors.

Implementations MAY wish to log the actions taken by FS actions (FSv1 or FSv2).

4.3. Error handling and Validation

The following two error handling rules must be followed by all BGP speakers which support FSv2:

The above two rules prevent any ambiguity that arises from the multiple copies of the same NLRI from multiple BGP FSv2 propagators.

A BGP implementation SHOULD treat such malformed NLRIs as ‘Treat-as-withdraw’ [RFC7606]

An implementation for a BGP speaker supporting both FSv1 and FSv2 MUST support the error handling for both FSv1 and FSv2.

5. Ordering for Flow Specification v2 (FSv2)

Flow Specification v2 allows the user to order flow specification rules and the actions associated with a rule. Each FSv2 rule has one or more match conditions and one or more actions associated with that match condition.

This section describes how to order FSv2 filters received from a peer prior to transmission to another peer. The same ordering should be used for the ordering of forwarding filtering installed based on only FSv2 filters.

Section 7.0 describes how a BGP peer that supports FSv1 and FSv2 should order the flow specification filters during the installation of these flow specification filters into FIBs or firewall engines in routers.

The BGP distribution of FSv1 NLRI and FSv2 NLRI and their associated path attributes for actions (Wide Communities and Extended Communities) is “ships-in-the-night” forwarding of different AFI/SAFI information. This recommended ordering provides for deterministic ordering of filters sent by the BGP distribution.

5.1. Ordering of FSv2 NLRI Filters

The basic principles regarding ordering of rules are simple:

Notes:

5.2. Ordering of the Actions

The FSv2 specification allows for actions to be associated by:

Actions may be ordered by user-defined action order number from 1-n (where n is 2**16-2 and the value 2**16-1 is reserved.

Byy default, extended community actions are associated with default order number 32768 [0x8000] or a specific configured value for the FSv2 domain.

Action user-order number zero is defined to have an Action type of “Set Action Chain operation” (ACO) (value 0x01) that defines the default action chain process. For details on “set action chain operation” see section 3.2.1 or section 5.2.1 below.

If the user-defined action number for two actions are the same, then the actions are ordered by FSv2 action types (see Table 3 for a list of action types). If the user-defined action number and the FSv2 action types are the same, then the order must be defined by the FSv2 action.

5.2.1. Action Chain Operation (ACO)

The “Action Chain Operation” (ACO) changes the way the actions after the current action in an action chain are handled after a failure. If no action chain operations are set, then the default action of “stop upon failure” (value 0x00) will be used for the chain.

5.2.1.1. Example 1 - Default ACO

Use Case 1: Rate limit to 600 packets per second

Description: The provider will support 600 packets per second All Packets sampled for reporting purposes and packet streams over 600 packets per second will be dropped.

Suppose BGP Peer A has a

  • a Wide Community action with user-defined order 10 with Traffic Sampling

  • a Wide Community action with user-defined order 11 from AS 2020 that limits packet-based rate limit of 600 packets per second.

  • an Extended Community from AS 2020 that does limits packet-based rate limit of 50 packets per second.

The FSv2 data base would store the following action chain:

  • at user-defined action order 10

    • A user action of type 7 (traffic action) with values of Sampling and logging.

  • at user-defined action order 11

    • a user action type of 12 (packet-based rate limit) with values of AS 2020 and float value for 600 packets per second (pps)

  • at user-defined action order 32768 (0x8000) with type 12 and values of A user action of type 12 with values of AS 2020 and float value of 50 packets/second.

Normal action:

  • The match on the traffic would cause a sample of the traffic (probably with packet rate saved in logging) followed by a rate limit to 600 pps. The Extended community action would further limit the rate to 50 packets per second.

When does the action chain stop?

  • The default process for the action chain is to stop on failure. If there is no failure, then all three actions would occur. This is probably not what the user wants.

  • If there is failure at action 10 (sample and log), then there would be no rate limiting per packet (actions 11 and action 32768).

  • If there is failure at action 11 (rate limit to packet 600), then there would be no rate limiting per packet (action 32768).

The different options for Action chain ordering (ACO) have been worked on with NETCONF/RESTCONF configuration and actions.

5.2.1.2. Example 2: Redirect traffic over limit to processing via SFC

Use case 2: Redirect traffic over limit to processing via SFC.

Description: The normal function is for traffic over the limit to be forwarded for offline processing and reporting to a customer.

Suppose we have the following 4 actions defined for a match:

  • Sent Redirect to indirection ID (0x01) with user-defined match 2 attached in wide community,

  • Traffic rate limit by bytes (0x07) with user-defined match 1 attached in wide community,

  • Traffic sample (0x07) sent in extended community, and

  • SF classifier Info (0x0E) sent in extended community.

These 4 filters rate limit a potential DDoS attack by: a) redirect the packet to indirection ID (for slower speed processing), sample to local hardware, and forward the attack traffic via a SFC to a data collection box.

The FSv2 action list for the match would look like this

  • Action 0: Operation of action chain (0x01) (stop upon failure)

  • Action 1: Traffic Rate limit by byte (0x07)

  • Action 2: Redirect to Redirection ID (0x0F)

  • Action 32768 (0x8000) Traffic Action (0x07) Sample

  • Action 32768 (0x8000) SFC Classifier: (0xE)

If the redirect to a redirection ID fails, then Traffic Sample and sending the data to an SFC classifier for forwarding via SFC will not happen. The traffic is limited, but not redirect away from the network and a sample sent to DDOS processing via a SFC classifier.

Suppose the following 5 actions were defined for a FSV2 filter:

  • Set Action Chain Operation (ACO) (0x01) to continue on failure (ox01) at user-order 2 attached in wide community,

  • redirect to indirection ID (0x0F) at user-order 2 attached in wide community,

  • traffic rate limit by bytes (0x07)with user-order 1 attached in wide community,

  • Traffic sample (0x07) attached via extended community, and

  • SFC classifier Info (0x0E) attached in extended community.

The FSv2 action list for the match would look like this:

  • Action 00: Operation of action chain (0x01) (stop upon failure)

  • Action 01:Traffic Rate limit by byte (0x07)

  • Action 02:Set Action Chain Operation (ACO) (0x01) (continue on failure)

  • Action 02: Redirect to Redirection ID (0F)

  • Action 32768 (0x8000): Traffic Action (0x07) Sample

  • Action 32768 (0x8000): SFC classifier (0x0E) forward via SFC [to DDoS classifier]

If the redirect to a redirection ID fails, the action chain will continue on to sample the data and enact SFC classifier actions.

5.2.2. Summary of FSv2 ordering

Operators should use user-defined ordering to clearly specify the actions desired upon a match. The FSv2 actions default ordering is specified to provide deterministic order for actions which have the same user-defined order and same type.


FS Action                          Value Order
(lowest value to highest)          (lowest to highest)
================================   ==============================
0x01: ACO: Action chain operation  Failure flag
0x02: TAIS:Traffic actions per     AS, then Group-ID, then Action ID
       Interface group

0x03-0x05 to be assigned           TBD
0x06: TRB: Traffic rate limit      AS, then float value
      by bytes
0x07: TA: Traffic Action           traffic action value
0x08: RDIP: Redirect to IP             AS, then IP Address, then ID
0x09: TM: Traffic Marking          DSCP value (lowest to highest)
0x0A: AL2: Associated L2 Info.     TBD
0x0B: AET: Associated E-tree Info. TBD
0x0C: TRP: Traffic Rate limit      AS, then float value
         by bytes
0x0D: RDIPv6: Traffic
        Redirect to IPv6           AS, IPv6 value, then local Admin
0x0E: TISFC: Traffic insertion
     to SFC                        SPI, then SI, the SFT
0xOF: Redirect to
          Indirection-ID           ID-type, then Generalized-ID

0x10: MPLSLA: MPLS Label stack     order, action, label, Exp
0x16 – VLAN action                 rewrite-actions, VALN1, VLAN2,
                                   PCP-DE1, PCP-DE2
0x17 – TPID action                 rewrite actions, TP-ID-1, TP-ID-2

                 Figure 6-1

6. Ordering of FS filters for BGP Peers support FSv1 and FSv2

FSv2 allows the user to order flow specification rules and the actions associated with a rule. Each FSv2 rule has one or more match conditions and one or more actions associated with each rule.

FSv1 and FSv2 filters are sent as different AFI/SAFI pairs so FSv1 and FSv2 operate as ships-in-the-night. Some BGP peers in an AS may support both FSv1 and FSv2. Other BGP peers may support FSv1 or FSv2. Some BGP will not support FSv1 or FSV2. A coherent flow specification technology must have consistent best practices for ordering the FSv1 and FSv2 filter rules.

One simple rule captures the best practice: Order the FSv1 filters after the FSv2 filter by placing the FSv1 filters after the FSv2 filters.

To operationally make this work, all flow specification filters should be included the same data base with the FSv1 filters being assigned a user- defined order beyond the normal size of FSv2 user-ordered values. A few examples, may help to illustrate this best practice.

Example 1: User ordered numbering - Suppose you might have 1,000 rules for the FSv2 filters. Assign all the FSv1 user defined rules to 1,001 (or better yet 2,000). The FSv1 rules will be ordered by the components and component values.

Example 2: Storage of actions - All FSv1 actions are defined ordered actions in FSv2. Translate your FSv1 actions into FSv2 ordered actions for storing in a common FSv1-FSv2 flow specification data base.

Example 3: Mixed Flow Specification Support -

      +---------+                       +---------+
      |    A    |=======================|    C    |
      |FSv1+FSv2|.                   . .|  FSv2   |
      +---------+ .                 .   +---------+
       ||  |   \   .               .      .     ||
       ||  |    \   . . . . . . . . .     .     ||
       ||  |     \               .   .    .     ||
       ||  |      \-----\      .      .   .     ||
       ||  |             \    .        .  .     ||
      +---------+       +------+       +-----+  ||
      |    E    |-------|  B   |. . . .|  D  |  ||
      |FSv1+FSv2|       | FSv1 |       |no FS|  ||
      +---------+       +------+       +-----+  ||
        ||     .                         .      ||
        ||     . . . . . . . . . . . . . .      ||
        ||                                      ||
        |========================================|

        Double line = FSv2
        Single line = FSv1
        Dotted line = BGP peering with no FlowSpec

         Figure 6-2: FSv1 and FVs2 Peering

7. Scalability and Aspirations for FSv2

Operational issues drive the deployment of BGP flow specification as a quick and scalable way to distribute filters. The early operations accepted the fact validation of the distribution of filter needed to be done outside of the BGP distribution mechanism. Other mechanisms (NETCONF/RESTCONF or PCEP) have reply-request protocols.

These features within BGP have not changed. BGP still does not have an action-reply feature.

NETCONF/RESTCONF latest enhancements provide action/response features which scale. The combination of a quick distribution of filters via BGP and a long-term action in NETCONF/RESTCONF that ask for reporting of the installation of FSv2 filters may provide the best scalability.

The combination of NETCONF/RESTCONF network management protocols and BGP focuses each protocol on the strengths of scalability.

FSv2 will be deployed in webs of BGP peers which have some BGP peers passing FSv1, some BGP peers passing FSv2, some BGP peers passing FSv1 and FSv2, and some BGP peers not passing any routes.

The TLV encoding and deterministic behaviors of FSv2 will not deprecate the need for careful design of the distribution of flow specification filters in this mixed environment. The needs of networks for flow specification are different depending on the network topology and the deployment technology for BGP peers sending flow specification.

Suppose we have a centralized RR connected to DDoS processing sending out flow specification to a second tier of RR who distribute the information to targeted nodes. This type of distribution has one set of needs for FSv2 and the transition from FSv1 to FSv2

Suppose we have Data Center with a 3-tier backbone trying to distribute DDoS or other filters from the spine to combinational nodes, to the leaf BGP nodes. The BGP peers may use RR or normal BGP distribution. This deployment has another set of needs for FSv2 and the transition from FSv1 to FSV2.

Suppose we have a corporate network with a few AS sending DDoS filters using basic BGP from a variety of sites. Perhaps the corporate network will be satisfied with FSv1 for a long time.

These examples are given to indicate that BGP FSv2, like so many BGP protocols, needs to be carefully tuned to aid the mitigation services within the network. This protocol suite starts the migration toward better tools using FSv2, but it does not end it. With FSv2 TLVs and deterministic actions, new operational mechanisms can start to be understood and utilized.

This FSv2 specification is merely the start of a revolution of work – not the end.

8. Optional Security Additions

This section discusses the optional BGP Security additions for BGP-FS v2 relating to BGPSEC [RFC8205] and ROA [RFC6482].

8.1. BGP FSv2 and BGPSEC

Flow specification v1 ([RFC8955] and [RFC8956]) do not comment on how BGP Flow specifications to be passed BGPSEC [RFC8205] BGP Flow Specification v2 can be passed in BGPSEC, but it is not required.

FSv1 and FSv2 may be sent via BGPSEC.

8.2. BGP FSv2 with ROA

BGP FSv2 can utilize ROAs in the validation. If BGP FSv2 is used with BGPSEC and ROA, the first thing is to validate the route within BGPSEC and second to utilize BGP ROA to validate the route origin.

The BGP-FS peers using both ROA and BGP-FS validation determine that a BGP Flow specification is valid if and only if one of the following cases:

The best match is defined to be the longest-match NLRI with the highest preference.

9. IANA Considerations

This section complies with [RFC7153].

9.1. Flow Specification V2 SAFIs

IANA is requested to assign two SAFI Values in the registry at https://www.iana.org/assignments/safi-namespace from the Standard Action Range as follows:

      Value   Description      Reference
     -----   -------------    ---------------
      TBD1   BGP FSv2        [this document]
      TBD2   BGP FSv2 VPN    [this document]

9.2. BGP Capability Code

IANA is requested to assign a Capability Code from the registry at https://www.iana.org/assignments/capability-codes/ from the IETF Review range as follows:

   Value   Description            Reference       Controller
   -----  ---------------------  ---------------  ----------
    TBD3  Flow Specification V2  [this document]  IETF

9.3. Filter IP Component types

IANA is requested to indicate [this draft] as a reference on the following assignments in the Flow Specification Component Types Registry:

Value  Description         Reference
-----  ------------------- ------------------------
 1     Destination filter  [RFC8955][RFC8956][this document]
 2     Source Prefix       [RFC8955][RFC8956][this document]
 3     IP Protocol         [RFC8955][RFC8956][this document]
 4     Port                [RFC8955][RFC8956][this document]
 5     Destination Port    [RFC8955][RFC8956][this document]
 6     Source Port         [RFC8955][RFC8956][this document]
 7     ICMP Type [v4 or v6][RFC8955][RFC8956][this document]
 8     ICMP Code [v4 or v6][RFC8955][RFC8956][this document]
 9     TCP Flags [v4]      [RFC8955][RFC8956][this document]
 10    Packet Length       [RFC8955][RFC8956][this document]
 11    DSCP marking        [RFC8955][RFC8956][this document]
 12    Fragment            [RFC8955][RFC8956][this document]
 13    Flow Label          [RFC8956][this document]
 14    TTL                 [this document]
 64    Partial SID         [draft-ietf-idr-flowspec-srv6]
                           [this document]
 65    MPLS Label Match 1  [this document]
                           [draft-ietf-idr-flowspec-mpls-match]
 66    MPLS Label Match 2  [this document]
                           [draft-ietf-idr-flowspec-mpls-match]

9.4. FSV2 NLRI TLV Types

IANA is requested to create the following two new registries on a new "Flow Specification v2 TLV Types” web page.

   Name: BGP FSv2 TLV types
   Reference: [this document]
   Registration Procedures: 0x01-0x3FFF Standards Action.

    Type          Use                     Reference
   -----          ---------------         ---------------
    0x00          Reserved                [this document]
    0x01          IP traffic rules        [this document]
    0x02          FSv2 Actions            [this document]
    0x03          L2 traffic rules        [this document]
    0x04          tunnel traffic rules    [this document]
    0x05          SFC AFI filter rules    [this document]
    0x06          BGP/MPLS VPN IP
                   traffic rules          [this document]
    0x07          BGP/MPLS VPN L2
                    traffic rules         [this document]
    0x08-0x3FFF   Unassigned              [this document]
    0x4000-0x7FFF Vendor specific         [this document]
    0x8000-0xFFFF Reserved                [this document]


   Name: BGP FSv2 Action types
   Reference: [this document]
   Registration Procedure: 0x01-0x3FFF Standards Action.

    Type     Use                           Reference
   -----  ---------------                 ---------------
   0x00   Reserved                        [this document]
   0x01   ACO: Action Chain Operation     [this document]
   0x02   TAIS: Traffic actions per
          interface group                 [this document]
   0x03   Unassigned                      [this document]
   0x04   Unassigned                      [this document]
   0x05   Unassigned                      [this document]
   0x06   TRB: traffic rate
           limited by bytes                [this document]
   0x07   TA: Traffic action
          (terminal/sample)               [this document]
   0x08   RDIPv4: redirect IPv4           [this document]
   0x09   TM: traffic marking (DSCP)      [this document]
   0x0A   AL2: associate L2 Information   [this document]
   0x0B   AET: associate E-Tree
           information                    [this document]
   0x0C   TRP: traffic rate
           limited by packets             [this document]
   0x0D   RDIPv6: Redirect to IPv6        [this document]

                      [this document]
   0x0F   RDIID: Redirect
           to indirection-iD              [this document]

   0x10 to assigned by expert review      [TBD]
   0x1F

   0x21   TISFC: Traffic insertion to SFC [this document]
   0x22   MPLS Label Action               [this document]
   0x23   VLAN action                     [this document]
   0x24   TIPD action                     [this document]
   0x25-
   0x3ff  Unassigned                      [this document]
   0x4000-
   0x7fff Vendor assigned                 [this document]
   0x8000-
   0xFFFF Reserved                        [this document]

9.5. Wide Community Assignments

IANA is requested to assign values in the BGP Community Container Atom Type Registry

   Name                    Type value
   -----                   -----------
   FSv2 action atom        TBD5

IANA is requested to assign values from the Registered BGP Wide Community Types:


   Name                    type Value
   ------                  -----------
   FSv2 Actions            Type-2 (suggested)

10. Security Considerations

The use of ROA improves on [RFC8955] by checking to see of the route origination. This check can improve the validation sequence for a multiple-AS environment.

>The use of BGPSEC [RFC8205] to secure the packet can increase security of BGP flow specification information sent in the packet.

The use of the reduced validation within an AS [RFC9117] can provide adequate validation for distribution of flow specification within a single autonomous system for prevention of DDoS.

Distribution of flow filters may provide insight into traffic being sent within an AS, but this information should be composite information that does not reveal the traffic patterns of individuals.

11. References

11.1. Normative References

[I-D.ietf-idr-bgp-flowspec-label]
liangqiandeng, Hares, S., You, J., Raszuk, R., and D. Ma, "Carrying Label Information for BGP FlowSpec", Work in Progress, Internet-Draft, draft-ietf-idr-bgp-flowspec-label-02, , <https://datatracker.ietf.org/doc/html/draft-ietf-idr-bgp-flowspec-label-02>.
[I-D.ietf-idr-flowspec-interfaceset]
Litkowski, S., Simpson, A., Patel, K., Haas, J., and L. Yong, "Applying BGP flowspec rules on a specific interface set", Work in Progress, Internet-Draft, draft-ietf-idr-flowspec-interfaceset-05, , <https://datatracker.ietf.org/doc/html/draft-ietf-idr-flowspec-interfaceset-05>.
[I-D.ietf-idr-flowspec-l2vpn]
Weiguo, H., Eastlake, D. E., Litkowski, S., and S. Zhuang, "BGP Dissemination of L2 Flow Specification Rules", Work in Progress, Internet-Draft, draft-ietf-idr-flowspec-l2vpn-23, , <https://datatracker.ietf.org/doc/html/draft-ietf-idr-flowspec-l2vpn-23>.
[I-D.ietf-idr-flowspec-mpls-match]
Yong, L., Hares, S., liangqiandeng, and J. You, "BGP Flow Specification Filter for MPLS Label", Work in Progress, Internet-Draft, draft-ietf-idr-flowspec-mpls-match-02, , <https://datatracker.ietf.org/doc/html/draft-ietf-idr-flowspec-mpls-match-02>.
[I-D.ietf-idr-flowspec-nvo3]
Eastlake, D. E., Weiguo, H., Zhuang, S., Li, Z., and R. Gu, "BGP Dissemination of Flow Specification Rules for Tunneled Traffic", Work in Progress, Internet-Draft, draft-ietf-idr-flowspec-nvo3-19, , <https://datatracker.ietf.org/doc/html/draft-ietf-idr-flowspec-nvo3-19>.
[I-D.ietf-idr-flowspec-path-redirect]
Van de Velde, G., Patel, K., and Z. Li, "Flowspec Indirection-id Redirect", Work in Progress, Internet-Draft, draft-ietf-idr-flowspec-path-redirect-12, , <https://datatracker.ietf.org/doc/html/draft-ietf-idr-flowspec-path-redirect-12>.
[I-D.ietf-idr-flowspec-srv6]
Li, Z., Li, L., Chen, H., Loibl, C., Mishra, G. S., Fan, Y., Zhu, Y., Liu, L., and X. Liu, "BGP Flow Specification for SRv6", Work in Progress, Internet-Draft, draft-ietf-idr-flowspec-srv6-05, , <https://datatracker.ietf.org/doc/html/draft-ietf-idr-flowspec-srv6-05>.
[I-D.ietf-idr-wide-bgp-communities]
Raszuk, R., Haas, J., Lange, A., Decraene, B., Amante, S., and P. Jakma, "BGP Community Container Attribute", Work in Progress, Internet-Draft, draft-ietf-idr-wide-bgp-communities-11, , <https://datatracker.ietf.org/doc/html/draft-ietf-idr-wide-bgp-communities-11>.
[RFC0791]
Postel, J., "Internet Protocol", STD 5, RFC 791, DOI 10.17487/RFC0791, , <https://www.rfc-editor.org/info/rfc791>.
[RFC2119]
Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, , <https://www.rfc-editor.org/info/rfc2119>.
[RFC3032]
Rosen, E., Tappan, D., Fedorkow, G., Rekhter, Y., Farinacci, D., Li, T., and A. Conta, "MPLS Label Stack Encoding", RFC 3032, DOI 10.17487/RFC3032, , <https://www.rfc-editor.org/info/rfc3032>.
[RFC4271]
Rekhter, Y., Ed., Li, T., Ed., and S. Hares, Ed., "A Border Gateway Protocol 4 (BGP-4)", RFC 4271, DOI 10.17487/RFC4271, , <https://www.rfc-editor.org/info/rfc4271>.
[RFC4360]
Sangli, S., Tappan, D., and Y. Rekhter, "BGP Extended Communities Attribute", RFC 4360, DOI 10.17487/RFC4360, , <https://www.rfc-editor.org/info/rfc4360>.
[RFC4760]
Bates, T., Chandra, R., Katz, D., and Y. Rekhter, "Multiprotocol Extensions for BGP-4", RFC 4760, DOI 10.17487/RFC4760, , <https://www.rfc-editor.org/info/rfc4760>.
[RFC5065]
Traina, P., McPherson, D., and J. Scudder, "Autonomous System Confederations for BGP", RFC 5065, DOI 10.17487/RFC5065, , <https://www.rfc-editor.org/info/rfc5065>.
[RFC5701]
Rekhter, Y., "IPv6 Address Specific BGP Extended Community Attribute", RFC 5701, DOI 10.17487/RFC5701, , <https://www.rfc-editor.org/info/rfc5701>.
[RFC6482]
Lepinski, M., Kent, S., and D. Kong, "A Profile for Route Origin Authorizations (ROAs)", RFC 6482, DOI 10.17487/RFC6482, , <https://www.rfc-editor.org/info/rfc6482>.
[RFC7153]
Rosen, E. and Y. Rekhter, "IANA Registries for BGP Extended Communities", RFC 7153, DOI 10.17487/RFC7153, , <https://www.rfc-editor.org/info/rfc7153>.
[RFC7606]
Chen, E., Ed., Scudder, J., Ed., Mohapatra, P., and K. Patel, "Revised Error Handling for BGP UPDATE Messages", RFC 7606, DOI 10.17487/RFC7606, , <https://www.rfc-editor.org/info/rfc7606>.
[RFC8174]
Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, , <https://www.rfc-editor.org/info/rfc8174>.
[RFC8955]
Loibl, C., Hares, S., Raszuk, R., McPherson, D., and M. Bacher, "Dissemination of Flow Specification Rules", RFC 8955, DOI 10.17487/RFC8955, , <https://www.rfc-editor.org/info/rfc8955>.
[RFC8956]
Loibl, C., Ed., Raszuk, R., Ed., and S. Hares, Ed., "Dissemination of Flow Specification Rules for IPv6", RFC 8956, DOI 10.17487/RFC8956, , <https://www.rfc-editor.org/info/rfc8956>.
[RFC9015]
Farrel, A., Drake, J., Rosen, E., Uttaro, J., and L. Jalil, "BGP Control Plane for the Network Service Header in Service Function Chaining", RFC 9015, DOI 10.17487/RFC9015, , <https://www.rfc-editor.org/info/rfc9015>.
[RFC9117]
Uttaro, J., Alcaide, J., Filsfils, C., Smith, D., and P. Mohapatra, "Revised Validation Procedure for BGP Flow Specifications", RFC 9117, DOI 10.17487/RFC9117, , <https://www.rfc-editor.org/info/rfc9117>.
[RFC9184]
Loibl, C., "BGP Extended Community Registries Update", RFC 9184, DOI 10.17487/RFC9184, , <https://www.rfc-editor.org/info/rfc9184>.

11.2. Informative References

[RFC6241]
Enns, R., Ed., Bjorklund, M., Ed., Schoenwaelder, J., Ed., and A. Bierman, Ed., "Network Configuration Protocol (NETCONF)", RFC 6241, DOI 10.17487/RFC6241, , <https://www.rfc-editor.org/info/rfc6241>.
[RFC8040]
Bierman, A., Bjorklund, M., and K. Watsen, "RESTCONF Protocol", RFC 8040, DOI 10.17487/RFC8040, , <https://www.rfc-editor.org/info/rfc8040>.
[RFC8205]
Lepinski, M., Ed. and K. Sriram, Ed., "BGPsec Protocol Specification", RFC 8205, DOI 10.17487/RFC8205, , <https://www.rfc-editor.org/info/rfc8205>.
[RFC8206]
George, W. and S. Murphy, "BGPsec Considerations for Autonomous System (AS) Migration", RFC 8206, DOI 10.17487/RFC8206, , <https://www.rfc-editor.org/info/rfc8206>.

Authors' Addresses

Susan Hares
Hickory Hill Consulting
7453 Hickory Hill
Saline, MI 48176
United States of America
Donald Eastlake
Futurewei Technologies
2386 Panoramic Circle
Apopka, FL 32703
United States of America
Chaitanya Yadlapalli
ATT
United States of America
Sven Maduschke
Verizon
Germany