Active and Passive Metrics and Methods (and everything in-between, or Hybrid)
draft-ietf-ippm-active-passive-04

Abstract

This memo provides clear definitions for Active and Passive performance assessment. The construction of Metrics and Methods can be described as Active or Passive. Some methods may use a subset of both active and passive attributes, and we refer to these as Hybrid Methods. This memo also describes multiple dimensions to help evaluate new methods as they emerge.

Status of This Memo

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This Internet-Draft will expire on June 12, 2016.

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Table of Contents

• 1. Introduction
• 1.1. Requirements Language
• 2. Purpose and Scope
• 3. Terms and Definitions
• 3.1. Performance Metric
• 3.2. Method of Measurement
• 3.3. Observation Point
• 3.4. Active Methods
• 3.5. Active Metric
• 3.6. Passive Methods
• 3.7. Passive Metric
• 3.8. Hybrid Methods and Metrics
• 4. Discussion
• 4.1. Graphical Representation
• 4.2. Discussion of PDM
• 4.3. Discussion of "Coloring" Method
• 4.4. Brief Discussion of OAM Methods
• 5. Security considerations
• 6. IANA Considerations
• 7. Acknowledgements
• 8. References
• 8.1. Normative References
• 8.2. Informative References
• Author's Address

1. Introduction

The adjectives "active" and "passive" have been used for many years to distinguish two different classes of Internet performance assessment. The first Passive and Active Measurement (PAM) Conference was held in 2000, but the earliest proceedings available on-line are from the second PAM conference in 2001 [https://www.ripe.net/ripe/meetings/pam-2001].

The notions of "active" and "passive" are well-established. In general:

• An Active metric or method depends on a dedicated measurement packet stream and observations of the stream.
• A Passive metric or method depends *solely* on observation of one or more existing packet streams. The streams only serve measurement when they are observed for that purpose, and are present whether measurements take place or not.

As new techniques for assessment emerge it is helpful to have clear definitions of these notions. This memo provides more detailed definitions, defines a new category for combinations of traditional active and passive techniques, and discusses dimensions to evaluate new techniques as they emerge.

This memo provides definitions for Active and Passive Metrics and Methods based on long usage in the Internet measurement community, and especially the Internet Engineering Task Force. This memo also describes the combination of fundamental Active and Passive categories, which are called Hybrid Methods and Metrics.

1.1. Requirements Language

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC 2119 [RFC2119].

2. Purpose and Scope

The scope of this memo is to define and describe Active and Passive versions of metrics and methods which are consistent with the long-time usage of these adjectives in the Internet measurement community and especially the Internet Engineering Task Force. Since the science of measurement is expanding, we provide a category for combinations of the traditional extremes, treating Active and Passive as a continuum and designating combinations of their attributes as Hybrid methods.

Further, this memo's purpose includes describing multiple dimensions to evaluate new methods as they emerge.

3. Terms and Definitions

This section defines the key terms of the memo. Some definitions use the notion of "stream of interest" which is synonymous with "population of interest" defined in clause 6.1.1 of ITU-T Recommendation Y.1540 [Y.1540]. The definitions are consistent with [I-D.zheng-ippm-framework-passive].

3.1. Performance Metric

The standard definition of a quantity, produced in an assessment of performance and/or reliability of the network, which has an intended utility and is carefully specified to convey the exact meaning of a measured value. (This definition is consistent with that of Performance Metric in [RFC2330] and [RFC6390]).

3.2. Method of Measurement

The procedure or set of operations having the object of determining a Measured Value or Measurement Result.

3.3. Observation Point

See section 2 of [RFC7011] for this definition (a location in the network where packets can be observed), and related definitions. The comparable term defined in IETF literature on Active measurement is Measurement Point, see section 4.1 of [RFC5835]. Both of these terms have come into use describing similar actions at the identified point in the network path.

3.4. Active Methods

Active measurement methods have the following attributes:

1. Active methods generate packet streams. Commonly, the packet stream of interest is generated as the basis of measurement. Sometimes, the adjective "synthetic" is used to categorize Active measurement streams [Y.1731]. Accompanying packet stream(s) may be generated to increase overall traffic load, though the loading stream(s) may not be measured.
2. The packets in the stream of interest have fields or field values (or are augmented or modified to include fields or field values) which are dedicated to measurement. Since measurement usually requires determining the corresponding packets at multiple measurement points, a sequence number is the most common information dedicated to measurement, and often combined with a timestamp.
3. The Source and Destination of the packet stream of interest are usually known a priori.
4. The characteristics of the packet stream of interest are known at the Source at least, and may be communicated to Destination as part of the method. Note that some packet characteristics will normally change during packet forwarding. Other changes along the path are possible, see [I-D.morton-ippm-2330-stdform-typep].

When adding traffic to the network for measurement, Active Methods influence the quantities measured to some degree, and those performing tests should take steps to quantify the effect(s) and/or minimize such effects.

3.5. Active Metric

An Active Metric incorporates one or more of the aspects of Active Methods in the metric definition.

For example, IETF metrics for IP performance (developed according to the [RFC2330] framework) include the Source packet stream characteristics as metric input parameters, and also specify the packet characteristics (Type-P) and Source and Destination IP addresses (with their implications on both stream treatment and interfaces associated with measurement points).

3.6. Passive Methods

Passive measurement methods are

• based solely on observations of undisturbed and unmodified packet stream of interest (in other words, the method of measurement MUST NOT add, change, or remove packets or fields, or change field values anywhere along the path).
• dependent on the existence of one or more packet streams to supply the stream of interest.
• dependent on the presence of the packet stream of interest at one or more designated observation points.

Some passive methods simply observe and collect information on all packets that pass Observation Point(s), while others filter the packets as a first step and only collect information on packets that match the filter criteria, and thereby narrow the stream of interest.

It is common that passive methods are conducted at one or more Observation Points. Passive methods to assess Performance Metrics often require multiple observation points, e.g., to assess latency of packet transfer across a network path between two Observation Points. In this case, the observed packets must include enough information to determine the corresponding packets at different Observation Points.

Communication of the observations (in some form) to a collector is an essential aspect of Passive Methods. In some configurations, the traffic load associated with results export to a collector may influence the network performance. However, the collection of results is not unique to Passive Methods, and the load from management and operations of measurement systems must always be considered for potential effects on the measured values.

3.7. Passive Metric

Passive Metrics apply to observations of packet traffic (traffic flows in [RFC7011]).

Passive performance metrics are assessed independent of the packets or traffic flows, and solely through observation. Some refer to such assessments as "out-of-band".

One example of passive performance metrics for IP packet transfer can be found in ITU-T Recommendation Y.1540 [Y.1540], where the metrics are defined on the basis of reference events generated as packet pass reference points. The metrics are agnostic to the distinction between active and passive when the necessary packet correspondence can be derived from the observed stream of interest as required.

3.8. Hybrid Methods and Metrics

Hybrid Methods are Methods of Measurement which use a combination of Active Methods and Passive Methods, to assess Active Metrics, Passive Metrics, or new metrics derived from the a priori knowledge and observations of the stream of interest. ITU-T Recommendation Y.1540 [Y.1540] defines metrics that are also applicable to the hybrid categories, since packet correspondence at different observation/reference points could be derived from "fields or field values which are dedicated to measurement", but otherwise the methods are passive.

There are several types of Hybrid methods, as categorized below.

With respect to a *single* stream of interest, Hybrid Type I methods fit in the continuum as follows, in terms of what happens at the Source (or Observation Point nearby):

• If you generate the stream of interest => Active
• If you augment or modify the stream of interest, or employ methods that modify the treatment of the stream => Hybrid Type I
• If you solely observe a stream of interest => Passive

As an example, consider the case where the method generates traffic load stream(s), and observes an existing stream of interest according to the criteria for Passive Methods. Since loading streams are an aspect of Active Methods, the stream of interest is not "solely observed", and the measurements involve a single stream of interest whose treatment has been modified both the presence of the load. Therefore, this is a Hybrid Type I method.

We define Hybrid Type II as follows: Methods that employ two or more different streams of interest with some degree of mutual coordination (e.g., one or more Active streams and one or more undisturbed and unmodified packet streams) to collect both Active and Passive Metrics and enable enhanced characterization from additional joint analysis. [I-D.trammell-ippm-hybrid-ps] presents a problem statement for Hybrid Type II methods and metrics. Note that one or more Hybrid Type I streams could be substituted for the Active streams or undisturbed streams in the mutually coordinated set. It is the Type II Methods where unique Hybrid Metrics are anticipated to emerge.

Methods based on a combination of a single (generated) Active stream and Passive observations applied to the stream of interest at intermediate observation points are also a type of Hybrid Methods. However, [RFC5644] already defines these as Spatial Metrics and Methods. It is possible to replace the Active stream of [RFC5644] with a Hybrid Type I stream and measure Spatial Metrics (but this was un-anticipated when [RFC5644] was developed).

The Table below illustrates the categorization of methods (where "Synthesis" refers to a combination of Active and Passive Method attributes).

                    | Single Stream          | Multiple Simultaneous 
                    | of Interest            | Streams of Interest
                    |                        | from Different Methods
====================================================================
Single Fundamental  | Active or Passive      | 
Method              |                        |

Synthesis of        | Hybrid Type I          | 
Fundamental Methods |                        |

Multiple Methods    | Spatial Metrics        | Hybrid Type II
                    | [RFC5644]              |

There may be circumstances where results measured with Hybrid Methods can be considered equivalent to Passive Methods. Referencing the notion of a "class C" where packets of different Type-P are treated equally in Section 13 of [RFC2330]and the terminology for paths from Section 5 of [RFC2330]:

Hybrid Methods of Measurement that augment or modify packets of a "class C" in a host should produce equivalent results to Passive Methods of Measurement, when hosts accessing and links transporting these packets along the path (other than those performing augmentation/modification) treat packets from both categories of methods (with and without the augmentation/modification) as the same "class C". The Passive Methods of Measurement represent the Ground Truth for comparisons of results between Passive and Hybrid methods, and this comparison should be conducted to confirm the class C treatment.

4. Discussion

This section illustrates the definitions and presents some examples.

4.1. Graphical Representation

If we compare the Active and Passive Methods, there are at least two dimensions on which methods can be evaluated. This evaluation space may be useful when a method is a combination of the two alternative methods.

The two dimensions (initially chosen) are:

Y-Axis:

"Effect of the measured stream on network conditions." The degree to which the stream of interest biases overall network conditions experienced by that stream and other streams. This is a key dimension for Active measurement error analysis. (Comment: There is also the notion of time averages - a measurement stream may have significant effect while it is present, but the stream is only generated 0.1% of the time. On the other hand, observations alone have no effect on network performance. To keep these dimensions simple, we consider the stream effect only when it is present, but note that reactive networks defined in [RFC7312] may exhibit bias for some time beyond the life of a stream.)

X-Axis:

"a priori Stream Knowledge." The degree to which stream characteristics are known a priori. There are methodological advantages of knowing the source stream characteristics, and having complete control of the stream characteristics. For example, knowing the number of packets in a stream allows more efficient operation of the measurement receiver, and so is an asset for active measurement methods. Passive methods (with no sample filter) have few clues available to anticipate what the protocol first packet observed will use or how many packets will comprise the flow, but once the standard protocol of a flow is known the possibilities narrow (for some compliant flows). Therefore this is a key dimension for Passive measurement error analysis.

There are a few examples we can plot on a two-dimensional space. We can anchor the dimensions with reference point descriptions.

Y-Axis:Effect of the measured stream on network conditions
^ Max 
|* Active using max capacity stream  
|
|
|
|
|* Active using stream with load of typical user
|
|
|
|* Active using extremely sparse, randomized stream
|                             * PDM                        Passive
| Min                                                            * 
+----------------------------------------------------------------|
|                                                                |
Stream          X-Axis: a priori Stream Knowledge        No Stream
Characteristics                                    Characteristics 
completely                                                   Known
known

We recognize that method categorization could be based on additional dimensions, but this would require a different graphical approach.

For example, "effect of stream of interest on network conditions" could easily be further qualified into:

1. effect on the performance of the stream of interest itself: for example, choosing a packet marking or DSCP resulting in domain treatment as a real-time stream (as opposed to default/best-effort marking.
2. effect on unmeasured streams that share the path and/or bottlenecks: for example, an extremely sparse measured stream of minimal size packets typically has little effect on other flows (and itself), while a stream designed to characterize path capacity may affect all other flows passing through the capacity bottleneck (including itself).
3. effect on network conditions resulting in network adaptation: for example, a network monitoring load and congestion conditions might change routing, placing some flows to alternate paths to mitigate the congestion.

We have combined 1 and 2 on the Y-axis, as examination of examples indicates strong correlation of effects in this pair, and network adaptation is not addressed.

It is apparent that different methods of IP network measurement can produce different results, even when measuring the same path at the same time. The two dimensions of the graph help to understand how the results might change with the method chosen. For example, an Active Method to assess throughput adds some amount of traffic to the network which might result in lower throughput for all streams. However, a Passive Method to assess throughput can also err on the low side due to unknown limitations of the hosts providing traffic, competition for host resources, limitations of the network interface, or private sub-networks that are not an intentional part of the path, etc. And Hybrid Methods could easily suffer from both forms of error. Another example of potential errors stems from the pitfalls of using an Active stream with known bias, such as a periodic stream defined in [RFC3432]. The strength of modelling periodic streams (like VoIP) is a potential weakness when extending the measured results to other application whose streams are non-periodic. The solutions are to model the application streams more exactly with an Active Method, or accept the risks and potential errors with the Passive Method discussed above.

4.2. Discussion of PDM

In [I-D.ietf-ippm-6man-pdm-option], an IPv6 Option Header for Performance and Diagnostic Measurements (PDM) is described which (when added to the stream of interest at strategic interfaces) supports performance measurements. This method processes a user traffic stream and adds "fields which are dedicated to measurement" (the measurement intent is made clear in the title of this option). Thus:

• The method intends to have a small effect on the measured stream and other streams in the network. There are conditions where this intent may not be realized.
• The measured stream has unknown characteristics until it is processed to add the PDM Option header. Note that if the packet MTU is exceeded after adding the header, the intent to have small effect will not be realized.

We conclude that this is a Hybrid Type I method, having at least one characteristic of both active and passive methods for a single stream of interest.

4.3. Discussion of "Coloring" Method

Draft [I-D.tempia-opsawg-p3m], proposed to color packets by re-writing a field of the stream at strategic interfaces to support performance measurements. This method processes a user traffic stream and inserts "fields or values which are dedicated to measurement". Thus:

[I-D.chen-ippm-coloring-based-ipfpm-framework] proposes a method similar to [I-D.tempia-opsawg-p3m], and ippm-list discussion indicates [I-D.chen-ippm-coloring-based-ipfpm-framework] may be covered by the same IPR as [I-D.tempia-opsawg-p3m].

• The method intends to have a small effect on the measured stream and other streams in the network (smaller than PDM above). There are conditions where this intent may not be realized.
• The measured stream has unknown characteristics until it is processed to add the coloring in the header, and the stream could be measured and time-stamped during that process.

We note that

We conclude that this is a Hybrid Type I method, having at least one characteristic of both active and passive methods for a single stream of interest.

4.4. Brief Discussion of OAM Methods

Many Operations, Administration, and Management (OAM) methods exist beyond the IP-layer. For example, [Y.1731] defines several different measurement methods which we would classify as follows:

• Loss Measurement (LM) occasionally injects frames with a count of previous frames since the last LM message. We conclude LM is Hybrid Type I because
  1. This method processes a user traffic stream,
  2. and augments the stream of interest with frames having "fields which are dedicated to measurement".
• Synthetic Loss Measurement (SLM) and Delay Measurement (DM) methods both inject dedicated measurement frames, so the "stream of interest is generated as the basis of measurement". We conclude that SLM and DM methods are Active Methods.

We also recognize the existence of alternate terminology used in OAM at layers other than IP. Readers are encouraged to consult [RFC6374] for MPLS Loss and Delay measurement terminology, for example.

5. Security considerations

When considering privacy of those involved in measurement or those whose traffic is measured, there is sensitive information communicated and observed at observation and measurement points described above. We refer the reader to the privacy considerations described in the Large Scale Measurement of Broadband Performance (LMAP) Framework [RFC7594], which covers active and passive measurement techniques and supporting material on measurement context.

6. IANA Considerations

This memo makes no requests for IANA consideration.

7. Acknowledgements

Thanks to Mike Ackermann for asking the right question, and for several suggestions on terminology. Brian Trammell provided key terms and references for the passive category, and suggested ways to expand the Hybrid description and types. Phil Eardley suggested some hybrid scenarios for categorization as part of his review. Tiziano Ionta reviewed the draft and suggested the classification for the "coloring" method of measurement. Nalini Elkins identified several areas for clarification following her review. Bill Jouris, Stenio Fernandes, and Spencer Dawkins suggested several editorial improvements. Tal Mizrahi, Joachim Fabini, Greg Mirsky and Mike Ackermann raised many key considerations in their WGLC reviews, based on their broad measurement experience.

8. References

8.1. Normative References

8.2. Informative References

Author's Address