Internet-Draft | Using STAMP for Segment Routing | April 2024 |
Gandhi, et al. | Expires 26 October 2024 | [Page] |
Segment Routing (SR) leverages the source routing paradigm. SR is applicable to both Multiprotocol Label Switching (SR-MPLS) and IPv6 (SRv6) data planes. This document describes procedures for Performance Measurement in SR networks using Simple Two-Way Active Measurement Protocol (STAMP) defined in RFC 8762 and its optional extensions defined in RFC 8972 and further augmented in RFC 9503. The procedure described is used for links, SR paths (including SR Policies and SR IGP Flexible Algorithm paths) as well as Layer-3 and Layer-2 services in SR networks, and is applicable to both SR-MPLS and SRv6 data planes.¶
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Segment Routing (SR) leverages the source routing paradigm and greatly simplifies network operations for Software Defined Networks (SDNs). SR is applicable to both Multiprotocol Label Switching (SR-MPLS) and IPv6 (SRv6) data planes [RFC8402]. SR takes advantage of the Equal-Cost Multipaths (ECMPs) between source and transit nodes, between transit nodes and between transit and destination nodes. SR Policies as defined in [RFC9256] are used to steer traffic through a specific, user-defined paths using a stack of Segments. A comprehensive SR Performance Measurement (PM) toolset is one of the essential requirements to measure network performance to provide Service Level Agreements (SLAs).¶
The Simple Two-Way Active Measurement Protocol (STAMP) provides capabilities for the measurement of various performance metrics in IP networks [RFC8762] without the use of a control channel to pre-signal session parameters. [RFC8972] defines optional extensions, in the form of TLVs, for STAMP. [RFC9503] augments that framework to define STAMP extensions for SR networks.¶
This document describes procedures for Performance Measurement in SR networks using STAMP defined in [RFC8762] and its optional extensions defined in [RFC8972] and further augmented in [RFC9503]. The procedure described is used for links, SR paths [RFC8402] (including SR Policies [RFC9256] and SR IGP Flexible Algorithm (Flex-Algo) paths [RFC9350]) as well as Layer-3 (L3) and Layer-2 (L2) services in SR networks, and is applicable to both SR-MPLS and SRv6 data planes.¶
STAMP requires protocol support on the Session-Reflector to process the received test packets, and hence the received test packets need to be punted from the fast path in data plane and return test packets need to be generated. This limits the scale for number STAMP sessions and the ability to provide faster measurement interval. This document enhances the procedure for Performance Measurement using STAMP to improve the scale for number of STAMP sessions and the interval for measurement of SR paths, for both SR-MPLS and SRv6 data planes by defining new measurement modes, one-way, loopback, and loopback with "timestamp and forward network programming function".¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "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.¶
ECMP: Equal Cost Multi-Path.¶
HMAC: Hashed Message Authentication Code.¶
I2E: Ingress-To-Egress.¶
IHS: Ingress-To-Egress, Hop-By-Hop or Select Scope.¶
L2: Layer-2.¶
L3: Layer-3.¶
MBZ: Must be Zero.¶
MNA: MPLS Network Action.¶
MPLS: Multiprotocol Label Switching.¶
PSID: Path Segment Identifier.¶
SHA: Secure Hash Algorithm.¶
SID: Segment ID.¶
SR: Segment Routing.¶
SRH: Segment Routing Header.¶
SR-MPLS: Segment Routing with MPLS data plane.¶
SRv6: Segment Routing with IPv6 data plane.¶
SSID: STAMP Session Identifier.¶
STAMP: Simple Two-Way Active Measurement Protocol.¶
TC: Traffic Class.¶
TSF: Timestamp and Forward.¶
TTL: Time-To-Live.¶
VPN: Virtual Private Network.¶
For performance measurement in SR networks, the STAMP Session-Sender and Session-Reflector can use the base STAMP test packets defined [RFC8762]. However, the STAMP test packets defined in [RFC8972] are preferred in SR environment because of the optional extensions. The STAMP test packets are encapsulated using IP/UDP header [RFC8762]. In this document, the STAMP test packets using IP/UDP header are used for SR networks, where the STAMP test packets are further encapsulated with an SR-MPLS header or IPv6 Segment Routing Header (IPv6/SRH).¶
The STAMP test packets are transmitted in performance measurement mode of two-way, one-way, loopback, or loopback with "timestamp and forward network programming function" in SR networks. Note that two-way measurement mode is referred to in STAMP process in [RFC8762] and is further described for SR networks in this document. The other measurement modes are new, described for SR networks in this document, are not defined by the STAMP process in [RFC8762].¶
The STAMP test packets are transmitted on the same path as the data traffic flow under measurement to measure delay and packet loss experienced by the data traffic flow by using the same SR encapsulation as the data traffic flow. The STAMP test packets carry the same SR-MPLS and IPv6/SRH headers as the data packets transmitted on the SR path and on the L3 and L2 service for the traffic flow under measurement.¶
Typically, STAMP reply test packets are transmitted along an IP path between Session-Reflector and Session-Sender. Matching forward direction path and return path for STAMP test packets, even for directly connected nodes are not guaranteed. It may be desired in SR networks that the same path (same set of links and nodes) between the Session-Sender and Session-Reflector be used for the STAMP test packets in both directions, for example, in an ECMP environment. This is achieved by using the optional STAMP extensions for SR-MPLS and SRv6 networks specified in [RFC9503] in two-way measurement mode. The STAMP Session-Reflector uses the return path parameters for the reply test packet from the STAMP extensions in the received Session-Sender test packet, as described in [RFC9503]. In case of loopback measurement mode, this is achieved by adding both forward direction path and return path in the SR-MPLS and IPv6/SRH encapsulation of the STAMP Session-Sender test packets.¶
The performance measurement procedure defined in this document is used to measure both delay and packet loss in SR networks based on the transmission and reception of STAMP test packets. The optional STAMP extensions defined in [RFC8972] are used for direct measurement in SR networks.¶
As shown in Figure 1, Reference Topology for two-way measurement mode, the STAMP Session-Sender S1 initiates a STAMP Session-Sender test packet and the STAMP Session-Reflector R1 generates and transmits a reply test packet. The reply test packet may be transmitted to the STAMP Session-Sender S1 on the same path (same set of links and nodes) or a different path in the reverse direction from the path taken towards the Session-Reflector R1.¶
The T1 is a transmit timestamp, and T4 is a receive timestamp added by node S1. The T2 is a receive timestamp, and T3 is a transmit timestamp added by node R1. All four timestamps are used by Session-Sender to measure round-trip delay as ((T4 - T1) - (T3 - T2)). Timestamps T1 and T2 are used by the Session-Sender to measure one-way delay as (T2 - T1), also referred to as near-end (forward direction) delay. Note that the delay value (T4 - T3) measured by Session-Sender is referred to as far-end (backward direction) one-way delay.¶
The one-way delay requires the clocks on the Session-Sender and Session-Reflector to be synchronized.¶
The nodes S1 and R1 may be connected via a link or an SR path with SR-MPLS or SRv6 data plane [RFC8402]. The link may be a physical interface, virtual link, or Link Aggregation Group (LAG) [IEEE802.1AX], or LAG member. The SR path may be an SR Policy [RFC9256] on node S1 (called "head-end") with destination to node R1 (called "tail-end") or SR IGP Flex-Algo path [RFC9350]. A Layer-3 (L3) and Layer-2 (L2) VPN service may be carried over the SR path.¶
An example STAMP Reference Model defined in [RFC8972] with some of the typical measurement parameters for a STAMP session is shown in Figure 2.¶
The Performance Measurement mode is two-way in this example.¶
The Destination UDP port number is selected for STAMP function as described in [RFC8762]. By default, Destination UDP port 862 is selected for STAMP sessions [RFC8762] for links, SR paths, and L3 and L2 services.¶
The Source UDP port is chosen by the Session-Sender. The same or different Source UDP port can be chosen for different STAMP sessions.¶
Session-Reflector mode can be Stateful or Stateless as described in Section 4 of [RFC8762]. Stateless mode may be desired in two-way measurement mode.¶
The SSID field in the STAMP test packets [RFC8972], and local configuration are used to identify the STAMP sessions that use two-way measurement mode.¶
When using the authentication mode for the STAMP sessions, the matching Authentication Type (e.g., HMAC-SHA-256) and Keychain is configured on Session-Sender and Session-Reflector [RFC8762].¶
Examples of the Timestamp Format is 64-bit truncated Precision Time Protocol (PTPv2) [IEEE.1588] and 64-bit Network Time Protocol (NTP) [RFC5905]. By default, the Session-Reflector replies in kind to the timestamp format received in the received Session-Sender test packet, as indicated by the "Z" flag in the Error Estimate field as described in [RFC8762] and it can be based on the Session-Reflector capability.¶
Examples of Delay Metric Type are one-way delay, round-trip delay, near-end (forward direction) and far-end (backward direction) delay as defined in [RFC8762].¶
Examples of Packet Loss Metric Type are round-trip, near-end (forward direction) and far-end (backward direction) packet loss as defined in [RFC8762].¶
A Software-Defined Networking (SDN) controller can be used for configuration and management of STAMP sessions as described in [RFC8762]. The controller can also receive streaming telemetry of operational data. The YANG data model for STAMP defined in [I-D.ietf-ippm-stamp-yang] can be used to configure Session-Senders and Session-Reflectors and to stream telemetry of operational data.¶
The content of an example Session-Sender test packet transmitted is shown in Figure 3. The payload containing the Session-Sender test packet, as defined in Section 3 of [RFC8972], is transmitted with IP and UDP header [RFC0768].¶
The Session-Sender test packet as shown in Figure 3 is transmitted over the link for delay measurement. The local and remote IP addresses of the link MUST be used as Source and Destination Addresses in the IP header of the Session-Sender test packets, respectively. For IPv6 links, the link local addresses [RFC7404] can be used in the IPv6 header. An SR encapsulation (e.g., containing local adjacency SID of the link) can also be added for transmitting the Session-Sender test packets for links.¶
The Session-Sender can use the local Address Resolution Protocol (ARP) table or any other similar method to obtain the IP and MAC addresses for the links for transmitting STAMP packets.¶
Note that the Session-Sender test packet is further encapsulated with a Layer-2 header containing Session-Reflector MAC address as the Destination MAC address and Session-Sender MAC address as the Source MAC address for Ethernet links.¶
For LAG member links, the STAMP extension for the Micro-Session ID TLV defined in [RFC9534] can be used to identify the member link.¶
An SR-MPLS path may be an SR-MPLS Policy [RFC9256] or SR-MPLS IGP Flex-Algo path [RFC9350].¶
A Candidate-Path of an SR-MPLS Policy can contain one or more Segment Lists. The Session-Sender test packets MUST be transmitted using each Segment List of the Candidate-Path of the SR-MPLS Policy for delay measurement.¶
Each SR-MPLS Segment List contains a list of 32-bit Label Stack Entry (LSE) that includes a 20-bit label value, 8-bit Time-To-Live (TTL) value, 3-bit Traffic-Class (TC) value and 1-bit End-Of-Stack (S) field.¶
The content of an example Session-Sender test packet for an SR-MPLS path using the same SR-MPLS encapsulation as the data traffic transmitted over the path is shown in Figure 4.¶
The head-end node address of the SR-MPLS Policy MUST be used as the Source Address in the IP header of the Session-Sender test packet. The endpoint address of the SR-MPLS Policy MUST be used as the Destination Address in the IP header of the Session-Sender test packet.¶
In case of Penultimate Hop Popping (PHP), the MPLS header is removed by the penultimate node. In this case, the Destination Address in the IP header ensures that the test packets reach the Session-Reflector on the SR-MPLS Policy endpoint.¶
In case of SR-MPLS Policy with Color-Only Destination Steering, with endpoint as unspecified address (the null endpoint is 0.0.0.0 for IPv4 or :: for IPv6 (all bits set to the 0 value)) as defined in Section 8.8.1 of [RFC9256], the loopback address from the range 127/8 for IPv4, or the loopback address ::1/128 for IPv6 [RFC4291] can be used as the Destination Address in the IP header of the Session-Sender test packets, respectively. In this case, the SR-MPLS encapsulation MUST ensure the Session-Sender test packets reach the SR Policy endpoint (for example, by adding the Prefix SID label of the SR-MPLS Policy endpoint in the Segment List).¶
The Path Segment Identifier (PSID) [RFC9545] of an SR-MPLS Policy (either for Segment List or for Candidate-Path) can be added in the Segment List of the STAMP test packets, and can be used for direct measurement as described in Section 9, "Direct Measurement in SR Networks".¶
Each IGP Flex-Algo in SR-MPLS networks [RFC9350] has Prefix SID labels advertised by the nodes. For delay measurement of SR-MPLS IGP Flex-Algo paths, the Session-Sender test packets carry the Flex-Algo Prefix SID label(s) of the Session-Sender and Session-Reflector in the MPLS header for that IGP Flex-Algo path under measurement.¶
For delay measurement of L3 service over SR-MPLS path, the same SR-MPLS label stack as the data packets transmitted over the L3 service including the L3VPN label (advertised by the Session-Reflector) is used to transmit Session-Sender test packets as shown in Figure 5.¶
An IP header as shown in Figure 3 is added in the Session-Sender test packets after the SR-MPLS encapsulation. The Destination Address added in the IP header MUST be reachable via the IP table lookup associated with the L3VPN label added for the L3 service on the Session-Reflector. The Source Address added in the IP header of the Session-Sender test packets MUST be reachable via the IP table lookup associated with the L3 service in the reverse direction.¶
For delay measurement of L2 service over SR-MPLS path, the same SR-MPLS label stack as the data packets transmitted over the L2 service including the L2VPN label (advertised by the Session-Reflector) is used to transmit Session-Sender test packets as shown in Figure 6.¶
The L2VPN label is added with a TTL value of 1 in order to punt the Session-Sender test packet from data plane to CPU or slow path on Session-Reflector for STAMP processing.¶
An IP header as shown in Figure 3 is added in the Session-Sender test packets after the MPLS header. It contains the Session-Sender Address as the Source Address and the Session-Reflector Address as the Destination Address.¶
An SRv6 path may be an SRv6 Policy [RFC9256] or SRv6 IGP Flex-Algo path [RFC9350].¶
A Candidate-Path of an SRv6 Policy can contain one or more Segment Lists. The Session-Sender test packets MUST be transmitted using each Segment List of the Candidate-Path of the SRv6 Policy for delay measurement.¶
The Segment Lists contain a number of SRv6 SIDs as defined in [RFC8986]. The Session-Sender test packets contain an IPv6 header and SRv6 Segment Routing Header (SRH) carrying Segment List as described in [RFC8754].¶
The content of an example Session-Sender test packet for an SRv6 path using the same IPv6/SRH encapsulation as the data traffic transmitted over the path is shown in Figure 7. The IPv6/SRH encapsulation can be encoded in Insert-Mode or Encaps-Mode. In Insert-Mode, an SRH is inserted after the IPv6 header of the test packets as shown in Example 1 of Figure 7. In Encaps-Mode, the test packets are encapsulated in an outer IPv6 header with an SRH as shown in Example 2 of Figure 7.¶
In outer IPv6/SRH header, the head-end node address of the SRv6 Policy MUST be used as the Source Address and the next Segment in the Segment List is used as the Destination Address. When Segment List of the Candidate-Path of the SRv6 Policy is empty, the endpoint address of the SRv6 Policy is added as the Destination Address.¶
In Encaps-Mode for IPv6, an inner IPv6 header added MUST contain the endpoint address of the SRv6 Policy as the Destination Address and the head-end node address of the SRv6 Policy as the Source Address. In case of SRv6 Policy with Color-Only Destination Steering, with endpoint as unspecified address (the null endpoint :: for IPv6 (all bits set to the 0 value)) as defined in Section 8.8.1 of [RFC9256], the loopback address ::1/128 for IPv6 [RFC4291] can be used as the Destination Address in the inner IPv6 header of the Session-Sender test packets. In this case, the Session-Sender MUST ensure that the Session-Sender test packets using the Segment List reach the Session-Reflector on the SRv6 Policy endpoint (for example, by adding the Prefix SID or the IPv6 address of the SRv6 Policy endpoint in the Segment List).¶
In case of Penultimate Segment Popping (PSP), the IPv6/SRH encapsulation is removed by the penultimate node. In Insert-Mode, the Session-Sender MUST ensure that the Session-Sender test packets using the Segment List reach the Session-Reflector on the SRv6 Policy endpoint (for example, by adding the Prefix SID or the IPv6 address of the SRv6 Policy endpoint in the Segment List).¶
The SRv6 network programming is described in [RFC8986]. The procedure defined for Upper-Layer (UL) Header processing for SRv6 End SIDs in Section 4.1.1 of [RFC8986] is used to process the UDP header in the received Session-Sender test packets on the Session-Reflector.¶
The Path Segment Identifier (PSID) [I-D.ietf-spring-srv6-path-segment] of the SRv6 Policy (either for Segment List or for Candidate-Path) can be added in the Segment List of the STAMP test packets and can be used for direct measurement as described in Section 9, "Direct Measurement in SR Networks".¶
Each IGP Flex-Algo in SRv6 networks [RFC9350] has Prefix SIDs advertised by the nodes. For delay measurement of SRv6 IGP Flex-Algo paths, the Session-Sender test packets carry the SRv6 Flex-Algo Prefix SIDs of the Session-Sender and Session-Reflector as the Source Address and Destination Address in the IPv6 header, respectively, for that SRv6 IGP Flex-Algo path under measurement.¶
For delay measurement of L3 service over SRv6 path, the same IPv6/SRH encapsulation as the data packets transmitted over the L3 service including the L3VPN SRv6 SID instantiated on the Session-Reflector (for example, End.DT6 SID instance, End.DT4 SID instance, End.DT46 instance, defined in [RFC8986]) is used to transmit Session-Sender test packets as shown in Figure 8 for both encoding modes, Insert-Mode and Encaps-Mode.¶
In Insert-Mode, an SRH is inserted after the IPv6 header of the STAMP test packets as shown in Example 1 of Figure 8. The IPv6 Source Address added in the IPv6 header MUST be reachable via the IPv6 table lookup for the L3 service in the reverse direction in case of End.DT6 and End.DT46 SIDs to return the reply test packets over that L3 service.¶
In Encaps-Mode, the STAMP test packets are encapsulated in outer IPv6 header with an SRH as shown in Examples 2 and 3 of Figure 8. An inner IP header is added in the Session-Sender test packets after the IPv6/SRH encapsulation.¶
The IPv6 Destination Address added in the inner IPv6 header MUST be reachable via the IPv6 table lookup associated with the L3VPN SRv6 SID added. Similarly, the IPv4 Destination Address added in the inner IPv4 header MUST be reachable via the IPv4 table lookup associated with the L3VPN SRv6 SID added.¶
The IPv6 Source Address added in the inner IPv6 header MUST be reachable via the IPv6 table lookup for the L3 service in the reverse direction to return the reply test packets over that L3 service. Similarly, the IPv4 Source Address added in the inner IPv4 header MUST be reachable via the IPv4 table lookup for the L3 service in the reverse direction.¶
For delay measurement of L2 service over SRv6 path, the same IPv6/SRH encapsulation as the data packets transmitted over the L2 service including the L2VPN SRv6 SID instantiated on the Session-Reflector (for example, End.DT2U SID instance defined in [RFC8986]) is used to transmit Session-Sender test packets as shown in Figure 9 for both encoding modes, Insert-Mode and Encaps-Mode.¶
In both encoding modes, the Session-Sender address is added as the Source Address and Session-Reflector address is added as the Destination Address in the outer IPv6 header.¶
In Insert-Mode, an SRH is inserted after the IPv6 header of the STAMP test packets as shown in Example 1 of Figure 9.¶
In Encaps-Mode, in addition to the outer IPv6/SRH encapsulation, an inner IPv6 header is added as shown in Example 2 of Figure 9, with Hop Limit value of 1 in order to punt the Session-Sender test packets from data plane to CPU or slow path on Session-Reflector for STAMP processing. The inner IPv6 header contains the Session-Sender Address as the Source Address and the Session-Reflector Address as the Destination Address.¶
In two-way measurement mode, reply test packets are transmitted by the Session-Reflector on the same or different path in the reverse direction for the STAMP sessions for links, SR paths and L3 and L2 services. It may be desired that the Session-Reflector test packets are transmitted on the return path that is same as the forward direction path in SR networks.¶
The Session-Reflector decapsulates the SR header (SR-MPLS header or IPv6/SRH) from the received Session-Sender test packets. The Session-Reflector test packet is generated using the information from the IP/UDP header of the received Session-Sender test packet as shown in Figure 10.¶
The payload contains the Session-Reflector test packet defined in Section 3 of [RFC8972].¶
For links, the Session-Sender may request in the test packet to the Session-Reflector to transmit the reply test packet on the same link in the reverse direction. It can use the "Reply Requested on the Same Link" flag in the Control Code Sub-TLV in the Return Path TLV defined in [RFC9503] for this request.¶
For SR paths, the Session-Sender may request in the test packet to the Session-Reflector to transmit the reply test packet on a specific SR return path. For example, reverse SR path associated with the forward direction SR path [I-D.ietf-pce-sr-bidir-path] or the Binding SID of the reverse SR Policy or the Prefix SID of the Session-Sender. It can use Segment List sub-TLV in the Return Path TLV defined in [RFC9503] for this request.¶
For SR IGP Flex-Algo paths, the Session-Sender may request in the test packet to the Session-Reflector to transmit the reply test packet on the same SR IGP Flex-Algo path in the reverse direction using Segment List sub-TLV in the Return Path TLV defined in [RFC9503].¶
For L3 services, the Session-Reflector can derive the L3 service in the reverse direction using the L3VPN SID received in the Session-Sender test packets to transmit the Session-Reflector test packets.¶
For L2 services, the Session-Reflector can derive the L2 service in the reverse direction using the L2VPN SID received in the Session-Sender test packets to transmit the Session-Reflector test packets.¶
As shown in Figure 11, Reference Topology for one-way measurement mode, the STAMP Session-Sender S1 initiates a Session-Sender test packet. The STAMP Session-Reflector does not generate and transmit reply test packets upon receiving Session-Sender test packets.¶
The T1 is a transmit timestamp added by node S1, T2 is a receive timestamp added by node R1. Timestamps T1 and T2 are used by the Session-Reflector to measure one-way delay as (T2 - T1).¶
The one-way delay requires the clocks on the Session-Sender and Session-Reflector to be synchronized.¶
In one-way measurement mode, Session-Sender test packets defined in Section 4 for STAMP sessions for links, SR paths, and L3 and L2 services are transmitted. The Session-Sender can request in the test packets to the Session-Reflector to not transmit reply test packets using the "No Reply Requested" flag in the Control Code Sub-TLV in the Return Path TLV defined in [RFC9503].¶
A Destination UDP port can be selected for one-way measurement mode, different than the Destination UDP port selected for two-way measurement mode, to not generate and transmit reply test packets. By default, the Destination UDP port 861 [RFC4656] is used in one-way measurement mode.¶
Stateful mode of Session-Reflector [RFC8762] may be desired in one-way measurement mode.¶
The SSID field in the received Session-Sender test packets, and local configuration are used to identify the STAMP sessions that use one-way measurement mode on Session-Sender and Session-Reflector.¶
As shown in Figure 12, Reference Topology for loopback measurement mode, STAMP Session-Sender S1 initiates a Session-Sender test packet to measure loopback delay of a bidirectional circular path. At STAMP Session-Reflector, the received Session-Sender test packets MUST NOT be punted out of the fast path in data plane (i.e., to slow path or control-plane) but simply forwarded. In other words, the Session-Reflector does not perform STAMP functions and generate Session-Reflector test packets.¶
The Session-Sender retrieves the timestamp T1 from the received Session-Sender test packet and collects the receive timestamp T4 locally. Both timestamps T1 and T4 are used to measure loopback delay as (T4 - T1). The loopback delay includes the STAMP test packet processing delay on the Session-Reflector component. The Session-Reflector processing delay component includes only the time required to loop the STAMP test packet from the incoming interface to the outgoing interface in the data plane. The Session-Reflector does not timestamp the test packets and hence does not need timestamping capability.¶
The Session-Sender MUST set the Destination UDP port to the UDP port it uses to receive the return Session-Reflector test packets (other than the Destination UDP ports 862 and 861 which are used by the Session-Reflector). The same UDP port can be used as Destination and Source UDP port in Session-Sender test packets as shown in Figure 13.¶
The IP header for the return path in the Session-Sender test packets MUST set the Destination Address equal to the Session-Sender address as shown in Figure 13 to return the test packets to the Session-Sender. The Session-Sender test packets are encapsulated with forward direction SR path and transmitted to Session-Reflector.¶
The Session-Reflector does not perform the STAMP process, as the loopback function simply processes the encapsulation including IP and SR headers (but does not process the UDP header) to forward the received Session-Sender test packet to the Session-Sender without STAMP modifications defined in [RFC8762].¶
The Session-Sender can use the SSID field in the received Session-Sender test packets, and local configuration to identify its STAMP sessions that use loopback measurement mode.¶
At the Session-Sender, the 'Session-Sender Sequence Number', 'Session-Sender Timestamp', 'Session-Sender Error Estimate', and 'Session-Sender TTL' fields MUST be set to zero in the transmitted Session-Sender test packets and MUST be ignored in the received test packets.¶
The Session-Sender test packets in loopback measurement mode may be transmitted with a Layer-2 header for the forward direction path as shown in Figure 14, containing the link MAC address on the Session-Reflector as the Destination Address and the link MAC address on the Session-Sender as the Source MAC address for Ethernet links.¶
An SR encapsulation (e.g., containing adjacency SID of the link) for the forward direction path can also be added after the Layer-2 header.¶
The IP header for the return path of the Session-Sender test packets is added and it MUST set the Source and Destination Address equal to the link address on the Session-Sender to return the test packet to the Session-Sender.¶
The Session-Reflector decapsulates the L2 header and forwards the test packet using the IP header for the return path to the Session-Sender.¶
In loopback measurement mode for SR-MPLS paths, the Session-Sender test packet can carry either the Segment List of the forward direction path only or both the forward direction and the return paths in MPLS header as shown in Figure 15.¶
An SR-MPLS path may be an SR-MPLS Policy [RFC9256] or SR-MPLS IGP Flex-Algo path [RFC9350].¶
In case of SR-MPLS Policy using Penultimate Hop Popping (PHP), the Session-Sender MUST ensure that the STAMP test packets reach the SR-MPLS Policy endpoint (for example, by adding the Prefix SID label of the SR-MPLS Policy endpoint in the Segment List of the forward direction path).¶
The IP header for the return path of the Session-Sender test packets is added and it MUST set the Destination Address equal to the Session-Sender address.¶
The Session-Sender test packets, in SR-MPLS label stack, carry return path, in addition to forward direction path. For example, they can carry the SR-MPLS label stack of the Segment List of the associated reverse Candidate-Path [I-D.ietf-pce-sr-bidir-path] or the Binding SID label of the reverse SR-MPLS Policy or the SR-MPLS Prefix SID label of the Session-Sender.¶
For SR-MPLS IGP Flex-Algo paths, Session-Sender test packets can carry the SR-MPLS Prefix SID label of the Session-Sender for the same SR-MPLS IGP Flex-Algo in the reverse direction.¶
In this case, the optional PSID is not added in the Session-Sender test packet.¶
The Session-Sender test packets in MPLS header carry the SR-MPLS label stack of the forward direction path only.¶
The Session-Reflector decapsulates the MPLS header and forwards the test packet using the IP header for the return path.¶
In this case, the optional PSID added in the Session-Sender test packet is for the SR-MPLS forward direction path and is allocated by the Session-Reflector.¶
In loopback measurement mode for L3 service over SR-MPLS path, the SR-MPLS label stack of the data packets transmitted over the L3 service is used to transmit Session-Sender test packets as shown in Figure 16.¶
The IP header for the return path of the Session-Sender test packets is added and it MUST set the Destination Address equal to the Session-Sender address. The Destination Address added in the IP header for the return path MUST be reachable via the IP table lookup associated with the L3VPN label added in the test packets.¶
The SR-MPLS label stack except the L3VPN label (advertised by the Session-Reflector) of the forward direction L3 service is added in the Session-Sender test packets. In addition, the SR-MPLS label stack including the L3VPN label for the reverse direction L3 service is also added in the Session-Sender test packets.¶
The SR-MPLS label stack including the L3VPN label (advertised by the Session-Reflector) of the forward direction L3 service is added in the Session-Sender test packets.¶
The Session-Reflector decapsulates the MPLS header and forwards the Session-Sender test packet using the IP header for the return path (after adding SR-MPLS encapsulation for the reverse direction L3 service).¶
In loopback measurement mode for L2 service over SR-MPLS path, the SR-MPLS label stack of the data packets transmitted over the L2 service is used to transmit Session-Sender test packets as shown in Figure 17.¶
The IP header for the return path MUST be added in the Session-Sender test packets that has the Destination Address equal to the Session-Sender address.¶
The SR-MPLS label stack except the L2VPN label (advertised by the Session-Reflector) of the forward direction L2 service is added in Session-Sender the test packets. In addition, the SR-MPLS label stack including the L2VPN label for the reverse direction L2 service is added the Session-Sender test packet with a TTL value of 1 in order to punt the test packet from data plane to CPU or slow path on Session-Sender for STAMP processing.¶
The STAMP test packets without using SR-MPLS return path is outside the scope of this document.¶
In loopback measurement mode for SRv6 paths, the Session-Sender test packet can carry either the Segment List of the forward direction path only using Encaps-Mode encoding or both the forward direction and the return paths in IPv6/SRH using Insert-Mode encoding as shown in Figure 18.¶
An SRv6 path may be an SRv6 Policy [RFC9256] or SRv6 IGP Flex-Algo path [RFC9350].¶
The Session-Sender MUST ensure that the Session-Sender test packets using the Segment List reach the SRv6 Policy endpoint (for example, by adding the Prefix SID or IPv6 address of the SRv6 Policy endpoint in the Segment List) in both encoding modes.¶
For SRv6 return path, the Session-Sender test packets are encoded in Insert-Mode as shown in Example 1 in Figure 18.¶
The Session-Sender test packets, in SRv6 Segment List, carry return path, in addition to forward direction path. For example, they can carry the Segment List of the associated reverse Candidate-Path [I-D.ietf-pce-sr-bidir-path] or the Binding SID of the reverse SRv6 Policy or the SRv6 Prefix SID of the Session-Sender.¶
For SRv6 IGP Flex-Algo paths, the Session-Sender test packets can carry the SRv6 Prefix SID of the Session-Sender for the same IGP Flex-Algo in the reverse direction.¶
In this case, the optional PSID is not added in the Session-Sender test packet.¶
For IP return path, the Session-Sender test packets are encoded in Encaps-Mode as shown in Example 2 in Figure 18.¶
The Session-Sender test packets carry the Segment List of the SRv6 forward direction path only.¶
An inner IP header for return path MUST be added in the Session-Sender test packets that has the Destination Address equal to the Session-Sender address to return the test packet to the Session-Sender.¶
The Session-Reflector decapsulates the IPv6/SRH headers and forwards the test packet using the inner IP header for the return path.¶
In this case, the optional PSID added in the Session-Sender test packet is for the SRv6 forward direction path and is allocated by the Session-Reflector.¶
In loopback measurement mode for L3 service over SRv6 path, the IPv6/SRH encapsulation of the data packets transmitted over the L3 service including the L3VPN SRv6 SID (for example, End.DT6 SID instance, End.DT4 SID instance, etc. defined in [RFC8986]) is used to transmit Session-Sender test packets as shown in Figure 19.¶
For SRv6 return path, the Session-Sender test packets are encoded in Insert-Mode as shown in Example 1 in Figure 19.¶
The SRv6 Segment List except the L3VPN SRv6 SID instantiated on the Session-Reflector of the forward direction L3 service is added in the IPv6/SRH encapsulation of the Session-Sender test packet. In addition, SRv6 Segment List including the L3VPN SRv6 SID instantiated on the Session-Sender for the reverse direction L3 service is also added in the IPv6/SRH encapsulation to return the test packet to the Session-Sender from the Session-Reflector.¶
For IP return path, the Session-Sender test packets are encoded in Encaps-Mode as shown in Examples 2 and 3 in Figure 19.¶
The SRv6 Segment List including the L3VPN SRv6 SID instantiated on the Session-Reflector for the forward direction L3 service is added in the IPv6/SRH encapsulation to transmit the Session-Sender test packet to the Session-Reflector.¶
An inner IP header for return path MUST also be added in the Session-Sender test packets that has the Destination Address equal to the Session-Sender address to forward the test packet to the Session-Sender from the Session-Reflector. In this case, the Destination Address added in the inner IP header for the return path MUST be reachable via the IPv4 or IPv6 table lookup associated with the L3VPN SRv6 SID on the Session-Reflector.¶
The Session-Reflector decapsulates the IPv6/SRH and forwards the Session-Sender test packet using the inner IP header for the return path (after adding IPv6/SRH encapsulation for the reverse direction L3 service).¶
In loopback measurement mode for L2 service over SRv6 path, the IPv6/SRH encapsulation of the data packets transmitted over the L2 service including the L2VPN SRv6 SID (for example, End.DT2U SID instance defined in [RFC8986]) is used to transmit Session-Sender test packets as shown in Figure 20.¶
For SRv6 return path, the Session-Sender test packets are encoded in Insert-Mode as shown in Figure 20.¶
The SRv6 Segment List except the L2VPN SRv6 SID instantiated on the Session-Reflector of the forward direction L2 service is added in the IPv6/SRH encapsulation of the Session-Sender test packet. In addition, SRv6 Segment List including the L2VPN SRv6 SID instantiated on the Session-Sender for the reverse direction L2 service is also added in the IPv6/SRH encapsulation to return the test packet to the Session-Sender from the Session-Reflector.¶
For IP return path, the Session-Sender test packets are encoded in Encaps-Mode. However, this mode is outside the scope of this document.¶
As shown in Figure 21, Reference Topology for "loopback measurement mode with timestamp and forward", STAMP Session-Sender S1 initiates a Session-Sender test packet in loopback measurement mode with network programming function. The network programming function is used to optimize the "operations of punt test packet and generate return test packet" on the STAMP Session-Reflector, as timestamping is implemented in fast path in data plane. This helps to achieve higher number of STAMP session scale and faster measurement interval.¶
The Session-Sender retrieves the timestamp T1 and T2 from the received Session-Sender test packet and collects the receive timestamp T4 locally. Timestamps T1 and T2 are used by the Session-Sender to measure one-way delay as (T2 - T1). Timestamps T1 and T4 are used by the Session-Sender to measure loopback delay as (T4 - T1).¶
The Session-Sender adds transmit timestamp (T1) in the payload of the Session-Sender test packet. The Session-Reflector adds the receive timestamp (T2) in the payload of the received test packet in fast path in data plane without punting the test packet (e.g., to slow path or control-plane) for STAMP packet processing. The network programming function carried by the test packet enables the Session-Reflector to add the "receive timestamp" (T2) at specific offset in the payload of the test packet.¶
The MPLS Network Action (MNA) Sub-Stack defined in [I-D.ietf-mpls-mna-hdr] is used for SR-MPLS paths for "timestamp and forward network programming function" for STAMP test packets. The MNA Sub-Stack carries the MNA Label (bSPL value TBA1) as defined in [I-D.ietf-mpls-mna-hdr]. A new MNA Opcode (value MNA.TSF) is defined for the network action for "Timestamp and Forward network programming function".¶
In the Session-Sender test packets for SR-MPLS paths, the MNA Sub-Stack with Opcode MNA.TSF is added in the MPLS header as shown in Figure 22, to collect timestamp in the "Receive Timestamp" field in the payload of the test packet from Session-Reflector. The Ingress-to-Egress (I2E), Hop-By-Hop (HBH), Select scope (IHS) is set to "I2E" when return path is IP/UDP. The Network Action Sub-Stack Length (NASL) is set to 0 when there is no LSE after the MNA.TSF Opcode in the MNA Sub-Stack. The U flag is set to skip the network action and forward the test packet (and not drop the packet).¶
The SR-MPLS label stack of the return path can be added after the MNA Sub-Stack to receive the return test packet on a specific path as described in loopback measurement for SR-MPLS path this document. The Ingress-to-Egress (I2E), Hop-By-Hop (HBH), Select scope (IHS) is set to "Select" in this case.¶
When a Session-Reflector receives a test packet with MNA Sub-Stack with Opcode MNA.TSF, after timestamping the test packet payload at specific offset, the Session-Reflector pops the MNA Sub-Stack (after completing any other network actions) and forwards the test packet as defined in loopback measurement mode for SR-MPLS path in this document.¶
New MPLS Network Action Opcode is defined called "Timestamp and Forward Network Action, MNA.TSF". The MNA.TSF Opcode is statically configured on the Session-Reflector node with a value from "Private Use from Range 111-126". The timestamp format for 64-bit PTPv2 and NTP to be added in the Session-Sender test packet payload is statically configured for MNA.TSF. The offset in the Session-Sender test packet payload (e.g., for unauthenticated mode with offset 16 bytes) is also statically configured for MNA.TSF.¶
The Session-Sender needs to know if the Session-Reflector can process the MNA Sub-Stack with Opcode MNA.TSF to avoid dropping the test packets. The signaling extension for this capability exchange or local configuration is outside the scope of this document.¶
The [RFC8986] defines SRv6 Endpoint Behaviours for SRv6 nodes. A new SRv6 Endpoint Behaviour is defined for "Timestamp and Forward (TSF) network programming function" for STAMP test packets.¶
In the Session-Sender test packets for SRv6 paths, Timestamp and Forward Endpoint Function (End.TSF) is carried with the target Segment Identifier (SID) in SRH [RFC8754] as shown in Figure 23, for both Insert-Mode and Encaps-Mode encoding, to collect timestamp in the "Receive Timestamp" field in the payload of the test packet from Session-Reflector.¶
The Session-Sender test packets are encoded in Insert-Mode for SRv6 return path and in Encaps-Mode for IP return path as defined in loopback measurement mode for SRv6 path in this document.¶
When a Session-Reflector receives a test packet with Timestamp and Forward Endpoint (End.TSF) for the target SID, which is local, after timestamping the test packet at specific offset, the Session-Reflector forwards the test packet as defined in loopback measurement mode for SRv6 paths.¶
New SRv6 Endpoint Behavior is defined called "Endpoint Behavior bound to SID with Timestamp and Forward (End.TSF)". The End.TSF is a node SID instantiated at Session-Reflector node. The End.TSF is statically configured on the Session-Reflector node and not advertised into the routing protocols. The timestamp format for 64-bit PTPv2 and NTP to be added in the Session-Sender test packet payload is statically configured for End.TSF. The offset in the Session-Sender test packet payload (e.g., for unauthenticated mode with offset 16 bytes) is also statically configured for End.TSF.¶
The Session-Sender needs to know if the Session-Reflector can process the Timestamp and Forward Endpoint Function to avoid dropping test packets. The signaling extension for this capability exchange or local configuration is outside the scope of this document.¶
The procedure described in Section 4 for delay measurement in SR networks using STAMP test packets also allows for round-trip, near-end (forward direction) and far-end (backward direction) inferred packet loss measurement in SR networks. This, however, provides only an approximate view of the data packet loss.¶
The loopback measurement mode and loopback measurement mode with timestamp and forward network programming function allow only the round-trip packet loss measurement.¶
The STAMP "Direct Measurement" TLV (Type 5) defined in [RFC8972] can be used in SR networks for data packet loss measurement. The STAMP test packets with this TLV are transmitted using the procedure described in Section 4 for delay measurement in SR networks using STAMP test packets to collect the Session-Sender transmit counters and Session-Reflector receive and transmit counters of the data packet flows for direct measurement.¶
The PSID carried in the received data packet for the traffic flow under measurement can be used to measure receive data packets (for receive traffic counter) for an SR path on the Session-Reflector.¶
In case of L3 and L2 services in SR networks, the associated SR-MPLS service labels and SRv6 service SIDs can be used to measure receive data packets (for receive traffic counters) on the Session-Reflector.¶
In loopback measurement mode and loopback measurement mode with timestamp and forward network programming function, the direct measurement is not applicable.¶
An SR path can have ECMPs between the source and transit nodes, between transit nodes and between transit and destination nodes. Usage of Anycast SID [RFC8402] by an SR path can result in ECMP paths via transit nodes, part of that Anycast group. The STAMP test packets need to be transmitted to traverse different ECMP paths to measure delay of an SR path.¶
Forwarding plane has various hashing functions available to forward packets on specific ECMP paths. The mechanisms described in [RFC8029] and [RFC5884] for handling ECMPs are also applicable to delay measurement.¶
For SR-MPLS paths, sweeping of MPLS entropy label [RFC6790] values can be used in Session-Sender test packets and Session-Reflector test packets to take advantage of the hashing function in data plane to influence the ECMP path taken by them.¶
In IPv4 header of the Session-Sender test packets and Session-Reflector test packets sweeping of Destination Address from the range 127/8 can be used to exercise ECMP paths taken by them when using MPLS header.¶
As specified in [RFC6437], Flow Label field in the outer IPv6 header can also be used for sweeping to exercise different IPv6 ECMP paths.¶
The threshold-based notification for delay and packet loss metrics may not be generated if the delay and packet loss metrics are not changing significantly. For an unambiguous monitoring, the controller may need to distinguish the cases whether the STAMP session is active, but delay and packet loss metrics are not changing significantly crossing the thresholds or the STAMP session has failed and not transmitting or receiving test packets.¶
The STAMP session state monitoring allows to know if the performance measurement test is active, idle or failed. The STAMP session state is notified as idle when Session-Sender is not transmitting test packets. The STAMP session state is initially notified as active when Session-Sender is transmitting test packets and as soon as one or more reply test packets are received at the Session-Sender.¶
The STAMP session state is notified as failed when consecutive N number of reply test packets are not received at the Session-Sender after the STAMP session state is notified as active, where N (consecutive packet loss count) is a locally provisioned value. In this case, the failed state of the STAMP session on the Session-Sender also indicates the connectivity (i.e., liveness) failure of the link, SR path or the L3/L2 service where the STAMP session was active.¶
The processing rules described in this section are applicable to the STAMP test packets for links, SR paths, and L3 and L2 services in SR networks.¶
The TTL field in the IPv4 and MPLS headers of the Session-Sender and Session-Reflector test packets MUST be set to 255 as per Generalized TTL Security Mechanism (GTSM) [RFC5082].¶
The Hop Limit (HL) field in all IPv6 headers of the Session-Sender and Session-Reflector test packets MUST be set to 255 as per Generalized TTL Security Mechanism (GTSM) [RFC5082].¶
The Router Alert IP option (RAO) [RFC2113] MUST NOT be set in the Session-Sender and Session-Reflector test packets to be able to punt the test packets using the Destination UDP port for STAMP.¶
The Flow Label field in the IPv6 header of the Session-Sender test packets is set to the value that is used by the data packets for the traffic flow on the SR path being measured by the Session-Sender.¶
The Session-Reflector SHOULD use the Flow Label value it received in the IPv6 header of the Session-Sender test packet in the reply test packet, and it can be based on the local configuration on the Session-Reflector.¶
For IPv4 STAMP test packets, where the local processor after adding the timestamp, is not capable of re-computing the UDP checksum or adding checksum complement [RFC7820], the Session-Sender and Session-Reflector can set the UDP checksum value to 0 [RFC8085].¶
For IPv6 STAMP test packets, where the local processor after adding the timestamp, is not capable of re-computing the UDP checksum or adding checksum complement [RFC7820], the Session-Sender and Session-Reflector can use the procedure defined in [RFC6936] for the UDP checksum (with value set to 0) for the UDP ports used for the STAMP sessions, and it can be based on the local policy.¶
Editorial note: Please remove this section prior to publication.¶
The following Cisco routing platforms running IOS-XR operating system have participated in an interop testing for one-way, two-way and loopback measurement modes for SR-MPLS and SRv6:¶
* Cisco 8802 (based Cisco Silicon One Q200)¶
* Cisco ASR9904 with Lightspeed linecard and Tomahawk linecard¶
* Cisco NCS5500 (based on Broadcom Jericho1 platform)¶
* Cisco NCS5700 (based on Broadcom Jericho2 platform)¶
The security considerations specified in [RFC8762], [RFC8972], and [RFC9503] also apply to the procedures described in this document.¶
Use of HMAC-SHA-256 in the authenticated mode protects the data integrity of the STAMP test packets. The message integrity protection using HMAC defined in Section 4.4 of [RFC8762] can be used with the procedure described in this document.¶
STAMP uses the well-known UDP port number that could become a target of denial of service (DoS) or could be used to aid on-path attacks. Thus, the security considerations and measures to mitigate the risk of the attack documented in Section 6 of [RFC8545] equally apply to the procedures described in this document.¶
The procedures defined in this document is intended for deployment in a single network administrative domain. As such, the Session-Sender address, Session-Reflector address, and forward direction and return paths are provisioned by the operator for the STAMP session. It is assumed that the operator has verified the integrity of the forward direction and return paths of the STAMP test packets.¶
When using the procedures defined in [RFC6936], the security considerations specified in [RFC6936] also apply.¶
The security considerations specified in [I-D.ietf-mpls-mna-hdr] are also applicable to the procedures for the SR-MPLS data plane defined in this document.¶
SRv6 STAMP test packets can use the HMAC protection authentication defined for SRH in [RFC8754].¶
The security considerations specified in [RFC8986] are also applicable to the procedures for the SRv6 data plane defined in this document.¶
This document does not require any IANA action.¶
The authors would like to thank Thierry Couture and Ianik Semco for the discussions on the use-cases for Performance Measurement in Segment Routing. The authors would also like to thank Greg Mirsky, Gyan Mishra, Xie Jingrong, and Mike Koldychev for reviewing this document and providing useful comments and suggestions. Patrick Khordoc, Haowei Shi, Amila Tharaperiya Gamage, Pengyan Zhang, Ruby Lin and Radu Valceanu have helped improve the mechanisms described in this document.¶
The following people have substantially contributed to this document:¶
Bart Janssens Colt Email: Bart.Janssens@colt.net¶
Navin Vaghamshi Reliance Email: Navin.Vaghamshi@ril.com¶
Moses Nagarajah Telstra Email: Moses.Nagarajah@team.telstra.com¶
Amit Dhamija Arrcus India Email: amitd@arrcus.com¶