Service Function Chaining | P. Quinn, Ed. |
Internet-Draft | Cisco |
Intended status: Standards Track | U. Elzur, Ed. |
Expires: January 26, 2018 | Intel |
C. Pignataro, Ed. | |
Cisco | |
July 25, 2017 |
Network Service Header (NSH)
draft-ietf-sfc-nsh-18
This document describes a Network Service Header (NSH) inserted onto packets or frames to realize service function paths. NSH also provides a mechanism for metadata exchange along the instantiated service paths. NSH is the SFC encapsulation required to support the Service Function Chaining (SFC) architecture (defined in RFC7665).
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 http://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 January 26, 2018.
Copyright (c) 2017 IETF Trust and the persons identified as the document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.
Service functions are widely deployed and essential in many networks. These service functions provide a range of features such as security, WAN acceleration, and server load balancing. Service functions may be instantiated at different points in the network infrastructure such as the wide area network, data center, campus, and so forth.
Prior to development of the SFC architecture [RFC7665] and the protocol specified in this document, current service function deployment models have been relatively static, and bound to topology for insertion and policy selection. Furthermore, they do not adapt well to elastic service environments enabled by virtualization.
New data center network and cloud architectures require more flexible service function deployment models. Additionally, the transition to virtual platforms requires an agile service insertion model that supports dynamic and elastic service delivery; the movement of service functions and application workloads in the network and the ability to easily bind service policy to granular information such as per-subscriber state and steer traffic to the requisite service function(s) are necessary.
Network Service Header (NSH) defines a new service plane protocol specifically for the creation of dynamic service chains and is composed of the following elements:
NSH is designed to be easy to implement across a range of devices, both physical and virtual, including hardware platforms.
An NSH-aware control plane is outside the scope of this document.
[RFC7665] provides an overview of a service chaining architecture that clearly defines the roles of the various elements and the scope of a service function chaining encapsulation. NSH is the SFC encapsulation referenced in [RFC7665].
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 RFC 2119.
NSH addresses several limitations associated with service function deployments. [RFC7498] provides a comprehensive review of those issues.
NSH creates a dedicated service plane, more specifically, NSH enables:
NSH contains service path information and optionally metadata that are added to a packet or frame and used to create a service plane. An outer transport header is imposed, on NSH and the original packet/frame, for network forwarding.
A Service Classifier adds NSH. NSH is removed by the last SFF in the service chain or by an SF that consumes the packet.
NSH is composed of a 4-byte Base Header, a 4-byte Service Path Header and optional Context Headers, as shown in Figure 1 below.
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Base Header | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Service Path Header | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | ~ Context Header(s) ~ | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 1: Network Service Header
Base header: provides information about the service header and the payload protocol.
Service Path Header: provides path identification and location within a service path.
Context header: carries metadata (i.e., context data) along a service path.
Figure 2 depicts the NSH base 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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |Ver|O|U| TTL | Length |U|U|U|U|MD Type| Next Protocol | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 2: NSH Base Header
Base Header Field Descriptions:
Version: The version field is used to ensure backward compatibility going forward with future NSH specification updates. It MUST be set to 0x0 by the sender, in this first revision of NSH. Given the widespread implementation of existing hardware that uses the first nibble after an MPLS label stack for ECMP decision processing, this document reserves version 01b and this value MUST NOT be used in future versions of the protocol. Please see [RFC7325] for further discussion of MPLS-related forwarding requirements.
O bit: Setting this bit indicates an Operations, Administration, and Maintenance (OAM) packet. The actual format and processing of SFC OAM packets is outside the scope of this specification (see for example [I-D.ietf-sfc-oam-framework] for one approach).
The O bit MUST be set for OAM packets and MUST NOT be set for non-OAM packets. The O bit MUST NOT be modified along the SFP.
SF/SFF/SFC Proxy/Classifier implementations that do not support SFC OAM procedures SHOULD discard packets with O bit set, but MAY support a configurable parameter to enable forwarding received SFC OAM packets unmodified to the next element in the chain. Forwarding OAM packets unmodified by SFC elements that do not support SFC OAM procedures may be acceptable for a subset of OAM functions, but can result in unexpected outcomes for others, thus it is recommended to analyze the impact of forwarding an OAM packet for all OAM functions prior to enabling this behavior. The configurable parameter MUST be disabled by default.
TTL: Indicates the maximum SFF hops for an SFP. This field is used for service plane loop detection. The initial TTL value SHOULD be configurable via the control plane; the configured initial value can be specific to one or more SFPs. If no initial value is explicitly provided, the default initial TTL value 63 MUST be used. Each SFF involved in forwarding an NSH packet MUST decrement the TTL value by 1 prior to NSH forwarding lookup. Decrementing by 1 from an incoming value of 0 shall result in a TTL value of 63. The packet MUST NOT be forwarded if TTL is, after decrement, 0.
All other flag fields are unassigned and available for future use, see Section 11.2.1. Unassigned bits MUST be set to zero upon origination and MUST be preserved unmodified by other NSH supporting elements. Elements which do not understand the meaning of any of these bits MUST NOT modify their actions based on those unknown bits.
Length: The total length, in 4-byte words, of NSH including the Base Header, the Service Path Header, the Fixed Length Context Header or Variable Length Context Header(s). The length MUST be of value 0x6 for MD Type equal to 0x1, and MUST be of value 0x2 or greater for MD Type equal to 0x2. The length of the NSH header MUST be an integer multiple of 4 bytes, thus variable length metadata is always padded out to a multiple of 4 bytes.
MD Type: indicates the format of NSH beyond the mandatory Base Header and the Service Path Header. MD Type defines the format of the metadata being carried. Please see the IANA Considerations Section 11.2.3.
This document specifies the following four MD Type values:
0x0 - this is a reserved value. Implementations SHOULD silently discard packets with MD Type 0x0.
0x1 - which indicates that the format of the header includes a fixed length Context Header (see Figure 4 below).
0x2 - which does not mandate any headers beyond the Base Header and Service Path Header, but may contain optional variable length Context Header(s). The semantics of the variable length Context Header(s) are not defined in this document. The format of the optional variable length Context Headers is provided in Section 2.5.1.
0xF - this value is reserved for experimentation and testing, as per [RFC3692]. Implementations not explicitly configured to be part of an experiment SHOULD silently discard packets with MD Type 0xF.
The format of the Base Header and the Service Path Header is invariant, and not affected by MD Type.
NSH implementations MUST support MD type = 0x1 and MD Type = 0x2 (where the length is of value 0x2). NSH implementations SHOULD support MD Type 0x2 with length > 0x2. There exists, however, a middle ground, wherein a device will support MD Type 0x1 (as per the MUST) metadata, yet be deployed in a network with MD Type 0x2 metadata packets. In that case, the MD Type 0x1 node, MUST utilize the base header length field to determine the original payload offset if it requires access to the original packet/frame. This specification does not disallow the MD Type value from changing along an SFP; however, the specification of the necessary mechanism to allow the MD Type to change along an SFP are outside the scope of this document, and would need to be defined for that functionality to be available. Packets with MD Type values not supported by an implementation MUST be silently dropped.
Next Protocol: indicates the protocol type of the encapsulated data. NSH does not alter the inner payload, and the semantics on the inner protocol remain unchanged due to NSH service function chaining. Please see the IANA Considerations section below, Section 11.2.5.
This document defines the following Next Protocol values:
0x0: Unassigned
0x1: IPv4
0x2: IPv6
0x3: Ethernet
0x4: NSH
0x5: MPLS
0xFE: Experiment 1
0xFF: Experiment 2
Packets with Next Protocol values not supported SHOULD be silently dropped by default, although an implementation MAY provide a configuration parameter to forward them. Additionally, an implementation not explicitly configured for a specific experiment [RFC3692] SHOULD silently drop packets with Next Protocol values 0xFE and 0xFF.
Figure 3 shows the format of the Service Path 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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Service Path Identifier (SPI) | Service Index | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ Service Path Identifier (SPI): 24 bits Service Index (SI): 8 bits
Figure 3: NSH Service Path Header
The meaning of these fields is as follows:
Service Path Identifier (SPI): identifies a service path. Participating nodes MUST use this identifier for Service Function Path selection. The initial classifier MUST set the appropriate SPI for a given classification result.
Service Index (SI): provides location within the SFP. The initial classifier for a given SFP SHOULD set the SI to 255, however the control plane MAY configure the initial value of SI as appropriate (i.e., taking into account the length of the service function path). Service Index MUST be decremented by a value of 1 by Service Functions or by SFC Proxy nodes after performing required services and the new decremented SI value MUST be used in the egress NSH packet. The initial Classifier MUST send the packet to the first SFF in the identified SFP for forwarding along an SFP. If re-classification occurs, and that re-classification results in a new SPI, the (re)classifier is, in effect, the initial classifier for the resultant SPI.
The SI is used in conjunction with Service Path Identifier for Service Function Path Selection and for determining the next SFF/SF in the path. The SI is also valuable when troubleshooting/ reporting service paths. Additionally, while the TTL field is the main mechanism for service plane loop detection, the SI can also be used for detecting service plane loops.
When the Base Header specifies MD Type = 0x1, a Fixed Length Context Header (16-bytes) MUST be present immediately following the Service Path Header, as per Figure 4. A Fixed Length Context Header that carries no metadata MUST be set to zero.
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |Ver|O|U| TTL | Length |U|U|U|U|MD Type| Next Protocol | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Service Path Identifier | Service Index | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | | Fixed Length Context Header | | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 4: NSH MD Type=0x1
This specification does not make any assumptions about the content of the 16 byte Context Header that must be present when the MD Type field is set to 1, and does not describe the structure or meaning of the included metadata.
An SFC-aware SF MUST receive the data semantics first in order to process the data placed in the mandatory context field. The data semantics include both the allocation schema and the meaning of the included data. How an SFC-aware SF gets the data semantics is outside the scope of this specification.
An SF or SFC Proxy that does not know the format or semantics of the Context Header for an NSH with MD Type 1 MUST discard any packet with such an NSH (i.e., MUST NOT ignore the metadata that it cannot process), and MUST log the event at least once per the SPI for which the event occurs (subject to thresholding).
[I-D.guichard-sfc-nsh-dc-allocation] and [I-D.napper-sfc-nsh-broadband-allocation] provide specific examples of how metadata can be allocated.
When the base header specifies MD Type = 0x2, zero or more Variable Length Context Headers MAY be added, immediately following the Service Path Header (see Figure 5). Therefore, Length = 0x2, indicates that only the Base Header followed by the Service Path Header are present. The optional Variable Length Context Headers MUST be of an integer number of 4-bytes. The base header Length field MUST be used to determine the offset to locate the original packet or frame for SFC nodes that require access to that information.
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |Ver|O|U| TTL | Length |U|U|U|U|MD Type| Next Protocol | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Service Path Identifier | Service Index | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | | ~ Variable Length Context Headers (opt.) ~ | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 5: NSH MD Type=0x2
The format of the optional variable length Context Headers, is as depicted in Figure 6.
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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Metadata Class | Type |U| Len | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Variable Metadata | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Figure 6: Variable Context Headers
Metadata Class (MD Class): defines the scope of the 'Type' field to provide a hierarchical namespace. The IANA Considerations Section 11.2.4 defines how the MD Class values can be allocated to standards bodies, vendors, and others.
Type: indicates the explicit type of metadata being carried and is the responsibility of the MD Class owner.
Unassigned bit: one unassigned bit is available for future use. This bit MUST be set to 0b.
Length: indicates the length of the variable metadata, in single byte words. In case the metadata length is not an integer number of 4-byte words, the sender MUST add pad bytes immediately following the last metadata byte to extend the metadata to an integer number of 4-byte words. The receiver MUST round up the length field to the nearest 4-byte word boundary, to locate and process the next field in the packet. The receiver MUST access only those bytes in the metadata indicated by the length field (i.e., actual number of single byte words) and MUST ignore the remaining bytes up to the nearest 4-byte word boundary. The Length may be 0 or greater.
A value of 0 denotes a Context Header without a Variable Metadata field.
This specification does not make any assumption about Context Headers that are mandatory-to-implement or those that are mandatory-to-process. These considerations are deployment-specific. However, the control plane is entitled to instruct SFC-aware SFs with the data structure of context header together with their scoping (see Section 3.3.3 of [I-D.ietf-sfc-control-plane]).
Upon receipt of a packet that belong to a given SFP, if a mandatory- to-process context header is missing in that packet, the SFC-aware SF MUST NOT process the packet and MUST log at least once per the SPI for which a mandatory metadata is missing.
If multiple mandatory-to-process context headers are required for a given SFP, the control plane MAY instruct the SFC-aware SF with the order to consume these Context Headers. If no instructions are provided, the SFC-aware SF MUST process these Context Headers in the order their appear in an NSH packet.
If multiple instances of the same metadata are included in an NSH packet, but the definition of that context header does not allow for it, the SFC-aware SF MUST process first instance and ignore subsequent instances.
NSH-aware nodes are the only nodes that may alter the content of NSH headers. NSH-aware nodes include: service classifiers, SFF, SF and SFC proxies. These nodes have several possible NSH-related actions:
Figure 7 maps each of the four actions above to the components in the SFC architecture that can perform it.
+----------------+---------------+-------+----------------+---------+ | | Insert |Forward| Update |Service | | | or remove NSH |NSH | NSH |policy | | | |Packets| |selection| | Component +-------+-------+ +----------------+ | | | | | | Dec. |Update | | | |Insert |Remove | |Service |Context| | | | | | | Index |Header | | +----------------+-------+-------+-------+--------+-------+---------+ | | + | + | | | + | | |Classifier | | | | | | | +--------------- +-------+-------+-------+--------+-------+---------+ |Service Function| | + | + | | | | |Forwarder(SFF) | | | | | | | +--------------- +-------+-------+-------+--------+-------+---------+ |Service | | | | + | + | + | |Function (SF) | | | | | | | +--------------- +-------+-------+-------+--------+-------+---------+ |SFC Proxy | + | + | | + | + | | +----------------+-------+-------+-------+--------+-------+---------+
Figure 7: NSH Action and Role Mapping
Once NSH is added to a packet, an outer encapsulation is used to forward the original packet and the associated metadata to the start of a service chain. The encapsulation serves two purposes:
The service header is independent of the encapsulation used and is encapsulated in existing transports. The presence of NSH is indicated via protocol type or other indicator in the outer encapsulation.
NSH and the associated transport header are "added" to the encapsulated packet/frame. This additional information increases the size of the packet.
As discussed in [I-D.ietf-rtgwg-dt-encap], within an administrative domain, an operator can ensure that the underlay MTU is sufficient to carry SFC traffic without requiring fragmentation.
However, there will be cases where the underlay MTU is not large enough to carry the NSH traffic. Since NSH does not provide fragmentation support at the service plane, the transport/overlay layer MUST provide the requisite fragmentation handling. Section 6 of [I-D.ietf-rtgwg-dt-encap] provides guidance for those scenarios.
As described above, NSH contains a Service Path Identifier (SPI) and a Service Index (SI). The SPI is, as per its name, an identifier. The SPI alone cannot be used to forward packets along a service path. Rather the SPI provides a level of indirection between the service path/topology and the network transport. Furthermore, there is no requirement, or expectation of an SPI being bound to a pre-determined or static network path.
The Service Index provides an indication of location within a service path. The combination of SPI and SI provides the identification of a logical SF and its order within the service plane, and is used to select the appropriate network locator(s) for overlay forwarding. The logical SF may be a single SF, or a set of eligible SFs that are equivalent. In the latter case, the SFF provides load distribution amongst the collection of SFs as needed.
SI serves as a mechanism for detecting invalid service function paths. In particular, an SI value of zero indicates that forwarding is incorrect and the packet must be discarded.
This indirection -- SPI to overlay -- creates a true service plane. That is the SFF/SF topology is constructed without impacting the network topology but more importantly service plane only participants (i.e., most SFs) need not be part of the network overlay topology and its associated infrastructure (e.g., control plane, routing tables, etc.) SFs need to be able to return a packet to an appropriate SFF (i.e., has the requisite NSH information) when service processing is complete. This can be via the over or underlay and in some case require additional configuration on the SF. As mentioned above, an existing overlay topology may be used provided it offers the requisite connectivity.
The mapping of SPI to transport occurs on an SFF (as discussed above, the first SFF in the path gets a NSH encapsulated packet from the Classifier). The SFF consults the SPI/ID values to determine the appropriate overlay transport protocol (several may be used within a given network) and next hop for the requisite SF. Table 1 below depicts an example of a single next-hop SPI/SI to network overlay network locator mapping.
SPI | SI | Next hop(s) | Transport |
---|---|---|---|
10 | 255 | 192.0.2.1 | VXLAN-gpe |
10 | 254 | 198.51.100.10 | GRE |
10 | 251 | 198.51.100.15 | GRE |
40 | 251 | 198.51.100.15 | GRE |
50 | 200 | 01:23:45:67:89:ab | Ethernet |
15 | 212 | Null (end of path) | None |
Additionally, further indirection is possible: the resolution of the required SF network locator may be a localized resolution on an SFF, rather than a service function chain control plane responsibility, as per Table 2 and Table 3 below.
Please note: VXLAN-gpe and GRE in the above table refer to [I-D.ietf-nvo3-vxlan-gpe] and [RFC2784], respectively.
SPI | SI | Next hop(s) |
---|---|---|
10 | 3 | SF2 |
245 | 12 | SF34 |
40 | 9 | SF9 |
SF | Next hop(s) | Transport |
---|---|---|
SF2 | 192.0.2.2 | VXLAN-gpe |
SF34 | 198.51.100.34 | UDP |
SF9 | 2001:db8::1 | GRE |
Since the SPI is a representation of the service path, the lookup may return more than one possible next-hop within a service path for a given SF, essentially a series of weighted (equally or otherwise) paths to be used (for load distribution, redundancy or policy), see Table 4. The metric depicted in Table 4 is an example to help illustrated weighing SFs. In a real network, the metric will range from a simple preference (similar to routing next- hop), to a true dynamic composite metric based on some service function-centric state (including load, sessions state, capacity, etc.)
SPI | SI | NH | Metric |
---|---|---|---|
10 | 3 | 203.0.113.1 | 1 |
203.0.113.2 | 1 | ||
20 | 12 | 192.0.2.1 | 1 |
203.0.113.4 | 1 | ||
30 | 7 | 192.0.2.10 | 10 |
198.51.100.1 | 5 |
(encapsulation type omitted for formatting)
As described above, the mapping of SPI to network topology may result in a single path, or it might result in a more complex topology. Furthermore, the SPI to overlay mapping occurs at each SFF independently. Any combination of topology selection is possible. Please note, there is no requirement to create a new overlay topology if a suitable one already existing. NSH packets can use any (new or existing) overlay provided the requisite connectivity requirements are satisfied.
Examples of mapping for a topology:
In the above example, each SFF makes an independent decision about the network overlay path and policy for that path. In other words, there is no a priori mandate about how to forward packets in the network (only the order of services that must be traversed).
The network operator retains the ability to engineer the network paths as required. For example, the overlay path between SFFs may utilize traffic engineering, QoS marking, or ECMP, without requiring complex configuration and network protocol support to be extended to the service path explicitly. In other words, the network operates as expected, and evolves as required, as does the service plane.
The SPI and SI serve an important function for visibility into the service topology. An operator can determine what service path a packet is "on", and its location within that path simply by viewing NSH information (packet capture, IPFIX, etc.) The information can be used for service scheduling and placement decisions, troubleshooting and compliance verification.
While a given realized service function path is a specific sequence of service functions, the service as seen by a user can actually be a collection of service function paths, with the interconnection provided by classifiers (in-service path, non-initial reclassification). These internal reclassifiers examine the packet at relevant points in the network, and, if needed, SPI and SI are updated (whether this update is a re-write, or the imposition of a new NSH with new values is implementation specific) to reflect the "result" of the classification. These classifiers may also of course modify the metadata associated with the packet.
[RFC7665], Section 2.1 describes Service Graphs in detail.
As described in Section 3, NSH provides the ability to carry metadata along a service path. This metadata may be derived from several sources, common examples include:
Regardless of the source, metadata reflects the "result" of classification. The granularity of classification may vary. For example, a network switch, acting as a classifier, might only be able to classify based on a 5-tuple, whereas, a service function may be able to inspect application information. Regardless of granularity, the classification information can be represented in NSH.
Once the data is added to NSH, it is carried along the service path, NSH-aware SFs receive the metadata, and can use that metadata for local decisions and policy enforcement. Figure 8 and Figure 9 highlight the relationship between metadata and policy:
+-------+ +-------+ +-------+ | SFF )------->( SFF |------->| SFF | +---^---+ +---|---+ +---|---+ ,-|-. ,-|-. ,-|-. / \ / \ / \ ( Class ) ( SF1 ) ( SF2 ) \ ify / \ / \ / `---' `---' `---' 5-tuple: Permit Inspect Tenant A Tenant A AppY AppY
Figure 8: Metadata and Policy
+-----+ +-----+ +-----+ | SFF |---------> | SFF |----------> | SFF | +--+--+ +--+--+ +--+--+ ^ | | ,-+-. ,-+-. ,-+-. / \ / \ / \ ( Class ) ( SF1 ) ( SF2 ) \ ify / \ / \ / `-+-' `---' `---' | Permit Deny AppZ +---+---+ employees | | +-------+ external system: Employee AppZ
Figure 9: External Metadata and Policy
In both of the examples above, the service functions perform policy decisions based on the result of the initial classification: the SFs did not need to perform re-classification, rather they rely on a antecedent classification for local policy enforcement.
Depending on the information carried in the metadata, data privacy considerations may need to be considered. For example, if the metadata conveys tenant information, that information may need to be authenticated and/or encrypted between the originator and the intended recipients (which may include intended SFs only) . NSH itself does not provide privacy functions, rather it relies on the transport/overlay layer. An operator can select the appropriate transport to ensure confidentially (and other security) considerations are met. Metadata privacy and security considerations are a matter for the documents that define metadata format.
Post-initial metadata imposition (typically performed during initial service path determination), metadata may be augmented or updated:
+-----+ +-----+ +-----+ | SFF |---------> | SFF |----------> | SFF | +--+--+ +--+--+ +--+--+ ^ | | ,---. ,---. ,---. / \ / \ / \ ( Class ) ( SF1 ) ( SF2 ) \ / \ / \ / `-+-' `---' `---' | Inspect Deny +---+---+ employees employee+ | | Class=AppZ appZ +-------+ external system: Employee
Figure 10: Metadata Augmentation
+-----+ +-----+ +-----+ | SFF |---------> | SFF |----------> | SFF | +--+--+ +--+--+ +--+--+ ^ | | ,---. ,---. ,---. / \ / \ / \ ( Class ) ( SF1 ) ( SF2 ) \ / \ / \ / `---' `---' `---' 5-tuple: Inspect Deny Tenant A Tenant A attack --> attack
Figure 11: Metadata Update
Metadata information may influence the service path selection since the Service Path Identifier values can represent the result of classification. A given SPI can be defined based on classification results (including metadata classification). The imposition of the SPI and SI results in the packet being placed on the newly specified SFP at the position indicated by the imposed SPI and SI.
This relationship provides the ability to create a dynamic service plane based on complex classification without requiring each node to be capable of such classification, or requiring a coupling to the network topology. This yields service graph functionality as described in Section 7.4. Figure 12 illustrates an example of this behavior.
+-----+ +-----+ +-----+ | SFF |---------> | SFF |------+---> | SFF | +--+--+ +--+--+ | +--+--+ | | | | ,---. ,---. | ,---. / \ / SF1 \ | / \ ( SCL ) ( + ) | ( SF2 ) \ / \SCL2 / | \ / `---' `---' +-----+ `---' 5-tuple: Inspect | SFF | Original Tenant A Tenant A +--+--+ next SF --> DoS | V ,-+-. / \ ( SF10 ) \ / `---' DoS "Scrubber"
Figure 12: Path ID and Metadata
Specific algorithms for mapping metadata to an SPI are outside the scope of this document.
As with many other protocols, NSH data can be spoofed or otherwise modified. In many deployments, NSH will be used in a controlled environment, with trusted devices (e.g., a data center) thus mitigating the risk of unauthorized header manipulation.
NSH is always encapsulated in a transport protocol and therefore, when required, existing security protocols that provide authenticity (e.g., [RFC6071]) can be used. Similarly, if confidentiality is required, existing encryption protocols can be used in conjunction with encapsulated NSH.
Further, existing best practices, such as [BCP38] should be deployed at the network layer to ensure that traffic entering the service path is indeed "valid". [I-D.ietf-rtgwg-dt-encap] provides additional transport encapsulation considerations.
NSH metadata authenticity and confidentiality must be considered as well. In order to protect the metadata, an operator can leverage the aforementioned mechanisms provided the transport layer, authenticity and/or confidentiality. An operator MUST carefully select the transport/underlay services to ensure end to end security services, when those are sought after. For example, if [RFC6071] is used, the operator MUST ensure it can be supported by the transport/underlay of all relevant network segments as well as SFF and SFs. Further, as described in Section 8.1, operators can and should use indirect identification for personally identifying information, thus significantly mitigating the risk of privacy violation. Means to prevent leaking privacy-related information outside an administrative domain are natively supported by NSH given that the last SFF of a path will systematically remove the NSH header before forwarding a packet upstream.
Lastly, SF security, although out of scope of this document, should be considered, particularly if an SF needs to access, authenticate or update NSH metadata.
This WG document originated as draft-quinn-sfc-nsh and had the following co-authors and contributors. The editors of this document would like to thank and recognize them and their contributions. These co-authors and contributors provided invaluable concepts and content for this document's creation.
Surendra Kumar
Cisco Systems
smkumar@cisco.com
Michael Smith
Cisco Systems
michsmit@cisco.com
Jim Guichard
Huawei
james.n.guichard@huawei.com
Rex Fernando
Cisco Systems
Email: rex@cisco.com
Navindra Yadav
Cisco Systems
Email: nyadav@cisco.com
Wim Henderickx
Alcatel-Lucent
wim.henderickx@alcatel-lucent.com
Andrew Dolganow
Alcaltel-Lucent
Email: andrew.dolganow@alcatel-lucent.com
Praveen Muley
Alcaltel-Lucent
Email: praveen.muley@alcatel-lucent.com
Tom Nadeau
Brocade
tnadeau@lucidvision.com
Puneet Agarwal
puneet@acm.org
Rajeev Manur
Broadcom
rmanur@broadcom.com
Abhishek Chauhan
Citrix
Abhishek.Chauhan@citrix.com
Joel Halpern
Ericsson
joel.halpern@ericsson.com
Sumandra Majee
F5
S.Majee@f5.com
David Melman
Marvell
davidme@marvell.com
Pankaj Garg
Microsoft
pankajg@microsoft.com
Brad McConnell
Rackspace
bmcconne@rackspace.com
Chris Wright
Red Hat Inc.
chrisw@redhat.com
Kevin Glavin
Riverbed
kevin.glavin@riverbed.com
Hong (Cathy) Zhang
Huawei US R&D
cathy.h.zhang@huawei.com
Louis Fourie
Huawei US R&D
louis.fourie@huawei.com
Ron Parker
Affirmed Networks
ron_parker@affirmednetworks.com
Myo Zarny
Goldman Sachs
myo.zarny@gs.com
The authors would like to thank Sunil Vallamkonda, Nagaraj Bagepalli, Abhijit Patra, Peter Bosch, Darrel Lewis, Pritesh Kothari, Tal Mizrahi and Ken Gray for their detailed review, comments and contributions.
A special thank you goes to David Ward and Tom Edsall for their guidance and feedback.
Additionally the authors would like to thank Larry Kreeger for his invaluable ideas and contributions which are reflected throughout this document.
Loa Andersson provided a thorough review and valuable comments, we thank him for that.
Reinaldo Penno deserves a particular thank you for his architecture and implementation work that helped guide the protocol concepts and design.
The editors also acknowledge comprehensive reviews and respective suggestions by Med Boucadair and Adrian Farrel.
Lastly, David Dolson has provides significant review, feedback and suggestions throughout the evolution of this document. His contributions are very much appreciated.
An IEEE EtherType, 0x894F, has been allocated for NSH.
IANA is requested to create a new "Network Service Header (NSH) Parameters" registry. The following sub-sections request new registries within the "Network Service Header (NSH) Parameters " registry.
There are five unassigned bits in the NSH Base Header. New bits are assigned via Standards Action [RFC8126].
Bit 3 - Unassigned
Bits 16-19 - Unassigned
IANA is requested to setup a registry of "NSH Version". New values are assigned via Standards Action [RFC8126].
Version 00b: This protocol version. This document.
Version 01b: Reserved. This document.
Version 10b: Unassigned.
Version 11b: Unassigned.
IANA is requested to set up a registry of "MD Types". These are 4-bit values. MD Type values 0x0, 0x1, 0x2, and 0xF are specified in this document, see Table 5. Registry entries are assigned by using the "IETF Review" policy defined in RFC 8126.
MD Type | Description | Reference |
---|---|---|
0x0 | Reserved | This document |
0x1 | NSH MD Type 1 | This document |
0x2 | NSH MD Type 2 | This document |
0x3..0xE | Unassigned | |
0xF | Experimentation | This document |
IANA is requested to set up a registry of "MD Class". These are 16- bit values. New allocations are to be made according to the following policies:
0x0000 to 0x01ff: IETF Review
0x0200 to 0xfff5: Expert Review
0xfff6 to 0xfffe: Experimental
0xffff: Reserved
IANA is requested to assign the values as per Table 6::
MD Class | Meaning | Reference |
---|---|---|
0x0000 | IETF Base NSH MD Class | This.I-D |
Designated Experts evaluating new allocation requests from the "Expert Review" range should principally consider whether a new MD class is needed compared to adding MD types to an existing class. The Designated Experts should also encourage the existence of an associated and publicly visible registry of MD types although this registry need not be maintained by IANA.
IANA is requested to set up a registry of "Next Protocol". These are 8-bit values. Next Protocol values 0, 1, 2, 3, 4 and 5 are defined in this document (see Table 7. New values are assigned via "Expert Reviews" as per [RFC8126].
Next Protocol | Description | Reference |
---|---|---|
0x0 | Unassigned | |
0x1 | IPv4 | This document |
0x2 | IPv6 | This document |
0x3 | Ethernet | This document |
0x4 | NSH | This document |
0x5 | MPLS | This document |
0x6..0xFD | Unassigned | |
0xFE | Experiment 1 | This document |
0xFF | Experiment 2 | This document |
This document requests IANA to create a registry for the type values owned by the IETF (i.e., MD Class set to 0x0000) called the "IETF Assigned MD Type Registry."
The type values are assigned via Standards Action [RFC8126].
No initial values are assigned at the creation of the registry.
[RFC2119] | Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997. |
[RFC7665] | Halpern, J. and C. Pignataro, "Service Function Chaining (SFC) Architecture", RFC 7665, DOI 10.17487/RFC7665, October 2015. |
[RFC8126] | Cotton, M., Leiba, B. and T. Narten, "Guidelines for Writing an IANA Considerations Section in RFCs", BCP 26, RFC 8126, DOI 10.17487/RFC8126, June 2017. |