Internet-Draft | O/TWAMP PM on LAG | August 2023 |
Li, et al. | Expires 1 March 2024 | [Page] |
This document defines extensions to One-way Active Measurement Protocol (OWAMP), and Two-way Active Measurement Protocol (TWAMP) to implement performance measurement on every member link of a Link Aggregation Group (LAG). Knowing the measured metrics of each member link of a LAG enables operators to enforce the performance based traffic steering policy across the member links.¶
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 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
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Link Aggregation Group (LAG), as defined in [IEEE802.1AX], provides mechanisms to combine multiple physical links into a single logical link. This logical link offers higher bandwidth and better resiliency, because if one of the physical member links fails, the aggregate logical link can continue to forward traffic over the remaining operational physical member links.¶
Usually, when forwarding traffic over LAG, the hash-based mechanism is used to load balance the traffic across the LAG member links. Link delay of each member link varies because of different transport paths. To provide low latency service for time sensitive traffic, we need to explicitly steer the traffic across the LAG member links based on the link delay, loss and so on. That requires a solution to measure the performance metrics of every member link of a LAG. Hence the measured performance metrics can work together with layer 2 bundle member link attributes advertisement [RFC8668] for traffic steering.¶
OWAMP [RFC4656] and TWAMP [RFC5357] are two active measurement methods according to the classification given in [RFC7799], which can complement passive and hybrid methods. With both methods, running a single test session over the aggregation without the knowledge of each member link would make it impossible to measure the performance of a given physical member link. The measured metrics can only reflect the performance of one member link or an average of some/all member links of the LAG.¶
This document extends OWAMP and TWAMP to implement performance measurement on every member link of a LAG. It can provide the same metrics as OWAMP and TWAMP can measure, such as delay, jitter and packet loss. The proposed method could also potentially apply to layer 3 ECMP (Equal Cost Multi-Path), e.g., with Segment Routing Policy [RFC9256].¶
This document intends to address the scenario (e.g., Figure 1) where a LAG (e.g., the LAG includes four member links) directly connects two nodes (A and B). The goal is to measure the performance of each link of the LAG.¶
To measure the performance metrics of every member link of a LAG, multiple sessions (one session for each member link) need to be established between the two end points that are connected by the LAG. These sessions are called micro sessions in the remainder of this document.¶
All micro sessions of a LAG share the same Sender IP Address and Receiver IP Address of the LAG. As for the UDP layer, the micro sessions may share the same Sender Port and Receiver Port pair, or each micro session is configured with a different Sender Port and Receiver Port pair. But from the operational point of view, the former is simpler and is RECOMMENDED.¶
The micro sessions need to associate with the corresponding member links. For example, when the Server/Reflector/Receiver receives a Test packet, it needs to know from which member link the packet is received, and correlate it with a micro session.¶
This document defines new command types to indicate the set of micro sessions of a LAG. The details are described in Sections 3 and 4 of this document. Upon receiving a Test packet, the receiver uses the receiving link's identifier to correlate the packet to a particular micro session. In addition, Test packets MAY carry the member link information for validation check. For example, when a micro Session-Sender receives a reflected Test packet, it may need to check whether the Test packet is from the expected member link.¶
To support the micro OWAMP session, a new command, Request-OW-Micro-Sessions (TBD1), is defined in this document. The Request-OW-Micro-Sessions command is based on the OWAMP Request-Session command, and uses the message format as described in Section 3.5 of OWAMP [RFC4656]. Test session creation of micro OWAMP session follows the same procedure as defined in Section 3.5 of OWAMP [RFC4656] with the following additions:¶
When an OWAMP Server receives a Request-OW-Micro-Sessions command, if the request is accepted, the OWAMP Server MUST build a set of micro sessions for all the member links of the LAG from which the Request-OW-Micro-Sessions message is received.¶
Micro OWAMP-Test reuses the OWAMP-Test packet format and procedures as defined in Section 4 of OWAMP [RFC4656] with the following additions:¶
The micro OWAMP Session-Sender MUST send the micro OWAMP-Test packets over the member link with which the session is associated. When receives a Test packet, the micro OWAMP Session-Receiver MUST use the member link from which the Test packet is received to correlate the micro OWAMP session. If there is no such a session, the Test packet MUST be discarded.¶
To support the micro TWAMP session, a new command, Request-TW-Micro-Sessions (TBD2), is defined in this document. The Request-TW-Micro-Sessions command is based on the TWAMP Request-Session command, and uses the message format as described in Section 3.5 of TWAMP [RFC5357]. Test session creation of micro TWAMP session follows the same procedure as defined in Section 3.5 of TWAMP [RFC5357] with the following additions:¶
When a TWAMP Server receives a Request-TW-Micro-Sessions command, if the request is accepted, the TWAMP Server MUST build a set of micro sessions for all the member links of the LAG from which the Request-TW-Micro-Sessions message is received.¶
The micro TWAMP-Test protocol is based on the TWAMP-Test protocol [RFC5357] with the following extensions.¶
The micro TWAMP Session-Sender packet format is based on the TWAMP Session-Sender packet format as defined in Section 4.1.2 of [RFC5357]. Two new fields (Sender Micro-session ID and Reflector Micro-session ID) are added to carry the LAG member link identifiers.¶
For unauthenticated mode, the format is as below:¶
For authenticated mode, the format is as below:¶
Except for the Sender/Reflector Micro-session ID field, all the other fields are the same as defined in Section 4.1.2 of TWAMP [RFC5357], which is defined in Section 4.1.2 of OWAMP [RFC4656]. Therefore, it follows the same procedure and guidelines as defined in Section 4.1.2 of TWAMP [RFC5357].¶
The micro TWAMP Session-Sender inherits the behaviors of the TWAMP Session-Sender as defined in Section 4.1 of [RFC5357]. In addition, the micro TWAMP Session-Sender MUST send the micro Session-Sender packets over the member link with which the session is associated.¶
When sending the Test packet, the micro TWAMP Session-Sender MUST put the Sender member link identifier that is associated with the micro TWAMP session in the Sender Micro-session ID. If the Session-Sender knows the Reflector member link identifier, the Reflector Micro-session ID field (see Figure 2 and Figure 3) MUST be set. Otherwise, the Reflector Micro-session ID field MUST be zero.¶
A Test packet with Sender member link identifier is sent to the Session-Reflector, and then is reflected with the same Sender member link identifier. So the Session-Sender can use the Sender member link identifier to check whether a reflected Test packet is received from the member link associated with the correct micro TWAMP session.¶
The Reflector member link identifier carried in the Reflector Micro-session ID field is used by the Session-Reflector to check whether a Test packet is received from the member link associated with the correct micro TWAMP session. It means that the Session-Sender has to learn the Reflector member link identifier. Once the Session-Sender knows the Reflector member link identifier, it MUST put the identifier in the Reflector Micro-session ID field (see Figure 2 or Figure 3) of the Test packets that will be sent to the Session-Reflector. The Reflector member link identifier can be obtained from pre-configuration or learned from the data plane (e.g., the reflected Test packet). How to obtain/learn the Reflector member link identifier is out of the scope of this document.¶
When receiving a reflected Test packet, the micro TWAMP Session-Sender MUST use the receiving member link to correlate the reflected Test packet to a micro TWAMP session. If there is no such a session, the reflected Test packet MUST be discarded. If a matched session exists, the micro Session-Sender MUST use the Sender Micro-session ID to validate whether the reflected Test packet is correctly transmitted over the expected member link. If the validation fails, the Test packet MUST be discarded. The micro Session-Sender MUST use the Reflector Micro-session ID to validate the Reflector's behavior. If the validation fails, the Test packet MUST be discarded.¶
The micro TWAMP Session-Reflector packet format is based on the TWAMP Session-Reflector packet format as defined in Section 4.2.1 of [RFC5357]. Two new fields (Sender and Reflector Micro-session ID) are added to carry the LAG member link identifiers.¶
For unauthenticated mode, the format is as below:¶
For authenticated mode, the format is as below:¶
Except for the Sender/Reflector Micro-session ID field, all the other fields are the same as defined in Section 4.2.1 of TWAMP [RFC5357]. Therefore, it follows the same procedure and guidelines as defined in Section 4.2.1 of TWAMP [RFC5357].¶
The micro TWAMP Session-Reflector inherits the behaviors of a TWAMP Session-Reflector as defined in Section 4.2 of [RFC5357].¶
In addition, when receiving a Test packet, the micro TWAMP Session-Reflector MUST use the receiving member link to correlate the Test packet to a micro TWAMP session. If there is no such a session, the Test packet MUST be discarded. If the Reflector Micro-session ID is not zero, the Reflector MUST use the Reflector Micro-session ID to validate whether it associates with the receiving member link. If the Reflector Micro-session ID is zero, it will not be verified. If the validation fails, the Test packet MUST be discarded.¶
When sending a response to the received Test packet, the micro TWAMP Session-Reflector MUST copy the Sender member link identifier from the received Test packet and put it in the Sender Micro-session ID field of the reflected Test packet (see Figure 4 and Figure 5). In addition, the micro TWAMP Session-Reflector MUST fill the Reflector Micro-session ID field (see Figure 4 and Figure 5) of the reflected Test packet with the member link identifier that is associated with the micro TWAMP session.¶
To set up the micro OWAMP sessions, the Control-Client firstly sends the Request-OW-Micro-Sessions command to the OWAMP Server. The OWAMP Server accepts the request, and builds a set of micro sessions for all the member links of the LAG.¶
For micro TWAMP sessions, the similar set up procedure as micro OWAMP sessions is used. Then the micro TWAMP Session-Sender sends micro Session-Sender packets with the Sender Micro-session ID and the Reflector Micro-session ID. The micro Session-Reflector checks whether a Test packet is received from the member link associated with the correct micro TWAMP session, if the Reflector Micro-session ID field is set. When reflecting, the micro TWAMP Session-Reflector copies the Sender Micro-session ID from the received micro Session-Sender packet to the micro Session-Reflector packet, and sets the Reflector Micro-session ID field with the member link identifier that is associated with the micro TWAMP session. When receiving the micro TWAMP Session-Reflector packet, the micro Session-Sender uses the the Sender Micro-session ID to check whether the packet is received from the member link associated with the correct micro TWAMP session. The micro Session-Sender also use the Reflector Micro-session ID to validate the Reflector's behavior.¶
This document requires the IANA to allocate the following command type from OWAMP-Control Command Number Registry.¶
Value Description Semantics Definition TBD1 Request-OW-Micro-Sessions This document, Section 3.1¶
This document requires the IANA to allocate the following command type from TWAMP-Control Command Number Registry.¶
Value Description Semantics Definition TBD2 Request-TW-Micro-Sessions This document, Section 4.1¶
This document does not introduce additional security requirements and mechanisms other than those described in [RFC4656], and [RFC5357].¶
The authors would like to thank Fang Xin, Henrik Nydell, Mach Chen, Min Xiao, Jeff Tantsura, Marcus Ihlar, Richard Foote for the valuable comments to this work.¶