One document matched: draft-ietf-ipfix-flow-selection-tech-12.txt
Differences from draft-ietf-ipfix-flow-selection-tech-11.txt
Internet Engineering Task Force S. D'Antonio
Internet-Draft University of Napoli
Intended status: Standards Track "Parthenope"
Expires: March 28, 2013 T. Zseby
CAIDA/FhG FOKUS
C. Henke
Tektronix Communication Berlin
L. Peluso
University of Napoli
September 24, 2012
Flow Selection Techniques
draft-ietf-ipfix-flow-selection-tech-12.txt
Abstract
Flow selection is the process of selecting a subset of Flows from all
observed Flows. The Intermediate Flow Selection Process may be
located at an IPFIX Exporter, Collector, or within an IPFIX Mediator.
Flow selection reduces the effort of post-processing Flow data and
transferring Flow Records. This document describes motivations for
Flow selection and presents Flow selection techniques. It provides
an information model for configuring Flow selection techniques and
discusses what information about an Intermediate Flow Selection
Process should be exported.
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].
Status of this Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF). Note that other groups may also distribute
working documents as Internet-Drafts. The list of current Internet-
Drafts is at 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."
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This Internet-Draft will expire on March 28, 2013.
Copyright Notice
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Table of Contents
1. Scope . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4
3. Difference between Flow Selection and Packet Selection . . . . 7
4. Flow selection within the IPFIX Architecture . . . . . . . . . 8
4.1. Flow selection in the Metering Process . . . . . . . . . . 10
4.2. Flow selection in the Exporting Process . . . . . . . . . 10
4.3. Flow selection as a function of the IPFIX Mediator . . . . 10
5. Flow Selection Techniques . . . . . . . . . . . . . . . . . . 10
5.1. Flow Filtering . . . . . . . . . . . . . . . . . . . . . . 11
5.1.1. Property Match Filtering . . . . . . . . . . . . . . . 11
5.1.2. Hash-based Flow Filtering . . . . . . . . . . . . . . 11
5.2. Flow Sampling . . . . . . . . . . . . . . . . . . . . . . 12
5.2.1. Systematic sampling . . . . . . . . . . . . . . . . . 12
5.2.2. Random Sampling . . . . . . . . . . . . . . . . . . . 12
5.3. Flow-state Dependent Flow Selection . . . . . . . . . . . 13
5.4. Flow-state Dependent Packet Selection . . . . . . . . . . 14
6. Configuration of Flow Selection Techniques . . . . . . . . . . 14
6.1. Intermediate Flow Selection Process Parameters . . . . . . 16
6.2. Description of Flow-state Dependent Packet Selection . . . 18
7. Information Model for Intermediate Flow Selection Process
Configuration and Reporting . . . . . . . . . . . . . . . . . 18
7.1. flowSelectorAlgorithm . . . . . . . . . . . . . . . . . . 20
7.2. flowSelectedOctetDeltaCount . . . . . . . . . . . . . . . 21
7.3. flowSelectedPacketDeltaCount . . . . . . . . . . . . . . . 21
7.4. flowSelectedFlowDeltaCount . . . . . . . . . . . . . . . . 21
7.5. selectorIDTotalFlowsObserved . . . . . . . . . . . . . . . 22
7.6. selectorIDTotalFlowsSelected . . . . . . . . . . . . . . . 22
7.7. samplingFlowInterval . . . . . . . . . . . . . . . . . . . 22
7.8. samplingFlowSpacing . . . . . . . . . . . . . . . . . . . 23
7.9. flowSamplingTimeInterval . . . . . . . . . . . . . . . . . 23
7.10. flowSamplingTimeSpacing . . . . . . . . . . . . . . . . . 24
7.11. hashFlowDomain . . . . . . . . . . . . . . . . . . . . . . 24
8. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 24
8.1. Registration of Information Elements . . . . . . . . . . . 24
8.2. Registration of Object Identifier . . . . . . . . . . . . 32
9. Security Considerations . . . . . . . . . . . . . . . . . . . 32
10. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 34
11. References . . . . . . . . . . . . . . . . . . . . . . . . . . 34
11.1. Normative References . . . . . . . . . . . . . . . . . . . 34
11.2. Informative References . . . . . . . . . . . . . . . . . . 34
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 36
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1. Scope
This document describes Flow selection techniques for network traffic
measurements. A Flow is defined as a set of packets with common
properties as described in [RFC5101]. Flow selection can be done to
limit the resource demands for capturing, storing, exporting and
post-processing of Flow Records. It also can be used to select a
particular set of Flows that are of interest to a specific
application. This document provides a categorization of Flow
selection techniques and describes configuration and reporting
parameters for them. In order to be compliant with this document, at
least the Property Match Filtering MUST be implemented.
This document also addresses configuration and reporting parameters
for Flow-state Dependent Packet Selection as described in [RFC5475],
although this technique is categorized as packet selection. The
reason is that Flow-state Dependent Packet Selection techniques often
aim at the reduction of resources for Flow capturing and Flow
processing. Furthermore, these techniques were only briefly
discussed in [RFC5475]. Therefore configuration and reporting
considerations for Flow-state Dependent Packet Selection techniques
have been included in this document.
2. Terminology
This document is consistent with the terminology introduced in
[RFC5101], [RFC5470], [RFC5475] and [RFC3917]. As in [RFC5101] and
[RFC5476], the first letter of each IPFIX-specific and PSAMP-specific
term is capitalized along with the Flow selection specific terms
defined here.
* Packet Classification
Packet Classification is a process by which packets are mapped to
specific Flow Records based on packet properties or external
properties (e.g. interface). The properties (e.g. header
information, packet content, AS number) make up the Flow Key. In
case a Flow Record for a specific Flow Key already exists the Flow
Record is updated, otherwise a new Flow Record is created.
* Packet Aggregation Process
In the IPFIX Metering Process the Packet Aggregation Process
aggregates packet data into Flow data and forms the Flow Records.
After the aggregation step only the aggregated Flow information is
available. Information about individual packets is lost.
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* Intermediate Flow Selection Process
An Intermediate Flow Selection Process takes Flow Records as its
input and selects a subset of this set as its output.
Intermediate Flow Selection Process is a more general concept than
Intermediate Selection Process as defined in [RFC6183]. While an
Intermediate Selection Process selects Flow Records from a
sequence based upon criteria-evaluated Flow record values and
passes only those Flow Records that match the criteria, an
Intermediate Flow Selection Process selects Flow Records using
selection criteria applicable to a larger set of Flow
characteristics and information.
* Flow Selection State
An Intermediate Flow Selection Process maintains state information
for use by the Flow Selector. At a given time, the Flow Selection
State may depend on Flows and packets observed at and before that
time, as well as other variables. Examples include:
(i) sequence number of packets and accounted Flow Records;
(ii) number of selected Flows;
(iii) number of observed Flows;
(iv) current Flow cache occupancy;
(v) Flow specific counters, lower and upper bounds;
(vi) Flow selection timeout intervals.
* Flow Selector
A Flow Selector defines the action of an Intermediate Flow
Selection Process on a single Flow of its input. The Flow
Selector can make use of the following information in order to
establish whether a Flow has to be selected or not:
(i) the content of the Flow Record;
(ii) any state information related to the Metering Process or
Exporting Process;
(iii) any Flow Selection State that may be maintained by the
Intermediate Flow Selection Process.
* Complete Flow
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A Complete Flow consists of all the packets that enter the
Intermediate Flow Selection Process within the Flow time-out
interval, and which belong to the same Flow as defined by the Flow
definition in [RFC5470]. For this definition only packets that
arrive at the Intermediate Flow Selection Process are considered.
* Flow Filtering
Flow Filtering selects flows based on a deterministic function on
the Flow Record content, Flow Selection State, external properties
(e.g. ingress interface) or external events (e.g violated Access
Control List). If the relevant parts of the Flow Record content
can already be observed at packet level (e.g. Flow Keys from
packet header fields) Flow Filtering can be performed at packet
level by Property Match Filtering as described in [RFC5475].
* Hash-based Flow Filtering
Hash-based Flow Filtering is a deterministic Flow filter function
that selects flows based on a Hash Function. The Hash Function is
calculated over parts of the Flow Record content or external
properties which are called the Hash Domain. If the hash value
falls into a predefined Hash Selection Range the Flow is selected.
Hash-based Flow Filtering can already applied at packet level, in
which case the Hash Domain MUST contain the Flow Key of the
packet. In case Hash-based Flow Filtering is used to select the
same subset of flows at different observation points, the Hash
Domain MUST comprise parts of the packet or Flow thar are
invariant on the packet/Flow path. Also refer to the according
Trajectory Sampling Application Example on packet level in
[RFC5475]
* Flow-state Dependent Flow Selection
Flow-state Dependent Flow Selection is a selection function that
selects or drops Flows based on the current Flow Selection State.
The selection can be either deterministic, random or non-uniform
random.
* Flow-state Dependent Packet Selection
Flow-state Dependent Packet Selection is a selection function that
selects or drops packets based on the current Flow Selection
State. The selection can be either deterministic, random or non-
uniform random. Flow-state Dependent Packet Selection can be used
to prefer the selection of packets belonging to specific Flows.
For example the selection probability of packets belonging to
Flows that are already within the Flow Cache may be higher than
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for packets that have not been recorded yet.
* Flow Sampling
Flow Sampling selects flows based on Flow Record sequence or
arrival times (e.g. entry in Flow cache, arrival time at Exporter
or Mediator). The selection can be systematic (e.g. every n-th
Flow) or based on a random function (e.g. select each Flow Record
with probability p, or randomly select n out of N Flow Records).
3. Difference between Flow Selection and Packet Selection
Flow selection differs from packet selection described in [RFC5475].
Packet selection techniques consider packets as the basic element and
the parent population consists of all packets observed at an
observation point. In contrast to this the basic elements in Flow
selection are the Flows. The parent population consists of all
observed Flows and the Intermediate Flow Selection Process operates
on the Flows. The major characteristics of Flow selection are the
following:
- Flow selection takes Flows as basic elements. For packet
selection, packets are considered as basic elements.
- Flow selection can only take place after Packet
Classification, because the classification rules determine to
which Flow a packet belongs. Packet selection can be applied
before and after Packet Classification. As an example,
packet selection before Packet Classification can be random
packet selection whereas packet selection after Packet
Classification can be Flow-state Dependent Packet Selection
(as described in [RFC5475])
- Flow selection operates on Complete Flows. That means that
after the Intermediate Flow Selection Process either all
packets of the Flow are kept or all packets of the Flow are
discarded. That means that if the Flow selection is preceded
by a packet selection process the Complete Flow consists only
of the packets that were not discarded during the packet
selection.
There are some techniques that are difficult to unambiguously
categorize into one of the categories. Here some guidance is given
on how to categorize such techniques:
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- Techniques that can be considered as both packet and Flow
selection: some packet selection techniques result in the
selection of Complete Flows and therefore can be considered
as packet or as Flow selection at the same time. An example
is Property Match Filtering of all packets to a specific
destination address. If Flows are defined based on
destination addresses, such a packet selection also results
in a Flow selection and can be considered as packet or Flow
selection.
- Flow-state Dependent Packet Selection: there exist techniques
that select packets based on the Flow state, e.g. based on
the number of already observed packets belonging to the Flow.
Examples of these techniques from the literature are "Sample
and Hold" [EsVa01] "Fast Filtered Sampling" [MSZC10] or the
"Sticky Sampling" algorithm presented in [MaMo02]. Such
techniques can be used to influence which Flows are captured
(e.g. increase the selection of packets belonging to large
Flows) and reduce the number of Flows that need to be stored
in the Flow cache. Nevertheless, such techniques do not
necessarily select Complete Flows, because they do not ensure
that all packets of a selected Flow are captured. Therefore
Flow-state Dependent Packet Selection techniques that do not
ensure that either all or no packets of a Flow are selected
strictly speaking have to be considered as packet selection
techniques and not as Flow selection techniques.
4. Flow selection within the IPFIX Architecture
An Intermediate Flow Selection Process can be deployed at any of
three places within the IPFIX architecture. As shown in Figure 1
Flow selection can occur
1. in the Metering Process at the IPFIX Exporter
2. in the Exporting Process at the Collector
3. within a Mediator
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+===========================================+
| IPFIX Exporter +----------------+ |
| | Metering Proc. | |
| +-----------------+ +----------------+ |
| | Metering | | Intermediate | |
| | Process | or | Flow Selection | |
| | | | Process | |
| +-----------------+----+----------------+ |
| | Exporting Process | |
| +----|-------------------------------|--+ |
+======|===============================|====+
| |
| |
+======|========================+ |
| | Mediator | |
+ +-V-------------------+ | |
| | Collecting Process | | |
+ +---------------------+ | |
| | Intermediate Flow | | |
| | Selection Process | | |
+ +---------------------+ | |
| | Exporting Process | | |
+ +-|-------------------+ | |
+======|========================+ |
| |
| |
+======|===============================|=====+
| | Collector | |
| +----V-------------------------------V-+ |
| | Collecting Process | |
| +--------------------------------------+ |
| | Intermediate Flow Selection Process | |
| +--------------------------------------+ |
| | Exporting Process | |
| +------------------------------|-------+ |
+================================|===========+
|
|
V
+------------------+
| IPFIX |
+------------------+
Figure 1: Potential Flow selection locations
In contrast to packet selection, Flow selection is always applied
after the packets are classified into Flows.
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4.1. Flow selection in the Metering Process
Flow selection in the Metering process uses packet information to
update the Flow Records in the Flow cache. Flow selection before
Packet Classification can be based on the fields of the Flow Key
(also on a hash value over these fields), but not based on
characteristics that are only available after Packet Classification
(e.g. Flow size, Flow duration). An Intermediate Flow Selection
Process is here applied to reduce resources for all succeeding
processes or to select specific Flows of interest in case such Flow
characteristics are already observable at packet level (e.g. Flows
to specific IP addresses). In contrast, Flow-state Dependent Packet
Selection is a packet selection technique, because it does not
necessarily select Complete Flows.
4.2. Flow selection in the Exporting Process
Flow selection in the Exporting Process works on Flow Records. An
Intermediate Flow Selection Process in the Exporting Process can
therefore depend on Flow characteristics that are only visible after
the classification of packets, such as Flow size and Flow duration.
The Exporting Process may implement policies for exporting only a
subset of the Flow Records which have been stored in the system
memory in order to unload Flow export and Flow post-processing. An
Intermediate Flow Selection Process in the Exporting Process may
select only the subset of Flow Records which are of interest to the
users application, or select only as many Flow Records as can be
handled by the available resources (e.g. limited export link
capacity).
4.3. Flow selection as a function of the IPFIX Mediator
As shown in Figure 1, Flow selection can be performed within an IPFIX
Mediator [RFC6183]. The Intermediate Flow Selection Process takes
Flow Record stream as its input and selects Flow Records from a
sequence based upon criteria-evaluated record values. The
Intermediate Flow Selection Process can again apply a Flow selection
technique to obtain Flows of interest to the application. Further,
the Intermediate Flow Selection Process can base its selection
decision on the correlation of data from different IPFIX Exporters,
e.g. by only selecting Flows that were at least recorded on two IPFIX
Exporters.
5. Flow Selection Techniques
A Flow selection technique selects either all or none of the packets
of a Flow, otherwise the technique has to be considered as packet
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selection. A difference is recognized between Flow Filtering and
Flow Sampling.
5.1. Flow Filtering
Flow Filtering is a deterministic function on the IPFIX Flow Record
content. If the relevant Flow characteristics are already observable
at packet level (e.g. Flow Keys), Flow Filtering can be applied
before aggregation at packet level. In order to be compliant with
this document, at least the Property Match Filtering MUST be
implemented.
5.1.1. Property Match Filtering
Property Match Filtering can be performed similarly to Property Match
Filtering for packet selection described in [RFC5475]. The
difference is that, instead of packet fields, Flow Record fields are
here used to derive the selection decision. Property Match Filtering
is typically used to select a specific subset of the Flows that are
of interest to a particular application (e.g. all Flows to a specific
destination, all large Flows, etc.). Properties on which the
filtering is based can be Flow Keys, Flow Timestamps, or Per-Flow
Counters described in [RFC5102]. Examples of properties are the Flow
size in bytes, the number of packets in the Flow, the observation
time of the first or last packet, or the maximum packet length. An
example is to select Flows with more than a threshold number of
observed octets. The selection criteria can be a specific value, a
set of specific values, or an interval. For example, a Flow is
selected if destinationIPv4Address and the total number of packets of
the Flow equal two predefined values. Property Match Filtering can
be applied in the Metering Process if the properties are already
observable at the packet level (e.g. Flow Key fields). For example,
a Flow is selected if sourceIPv4Address and sourceIPv4PrefixLength
equal, respectively, two specific values.
There are content-based Property Match Filtering techniques that
require a computation on the current Flow cache. An example is the
selection of the largest Flows or a percentage of Flows with the
longest lifetime. This type of Property Match Filtering is also used
in Flow selection techniques that react to external events (e.g.
resource constraint). For example when the Flow cache is full, the
Flow Record with the lowest Flow volume per current Flow life time
may be deleted.
5.1.2. Hash-based Flow Filtering
Hash-based Flow Filtering uses a Hash Function h to map the Flow Key
c onto a Hash Range R. A Flow is selected if the hash value h(c) is
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within the Hash Selection Range S, which is a subset of R. Hash-based
Flow Filtering can be used to emulate a random sampling process but
still enable the correlation between selected Flow subsets at
different observation points. Hash-based Flow Filtering is similar
to Hash-based Packet Selection, and in fact is identical when Hash-
based Packet Selection uses the Flow Key that defines the Flow as the
hash input. Nevertheless there may be the incentive to apply Hash-
based Flow Filtering not on the packet level in the Metering Process,
for example when the size of the selection range and therefore the
sampling probability is dependent on the number of observed Flows.
5.2. Flow Sampling
Flow Sampling operates on Flow Record sequence or arrival times. It
can use either a systematic or a random function for the Intermediate
Flow Selection Process. Flow Sampling usually aims at the selection
of a representative subset of all Flows in order to estimate
characteristics of the whole set (e.g. mean Flow size in the
network).
5.2.1. Systematic sampling
Systematic sampling is a deterministic selection function.
Systematic sampling may be a periodic selection of the N-th Flow
Record which arrives at the Intermediate Flow Selection Process.
Systematic sampling MAY be applied in the Metering Process. An
example would be to create, besides the Flow cache of selected Flows,
an additional data structure that saves the Flow Keys of the Flows
that are not selected. The selection of a Flow would then be based
on the first packet of a Flow. Everytime a packet belonging to a new
Flow (which is neither in the data structure of the selected or not
selected Flows) arrives at the Observation Point, a counter is
increased. In case the counter is increased to a multiple of N a new
Flow cache entry is created, and in case the counter is not a
multiple of N the Flow Key is added to the data structure for not
selected Flows.
Systematic sampling can also be time-based. Time-based systematic
sampling is applied by only creating Flows that are observed between
time-based start and stop triggers. The time interval may be applied
at packet level in the Metering Process or after aggregation on Flow
level, e.g. by selecting a Flow arriving at the Exporting Process
every n seconds.
5.2.2. Random Sampling
Random Flow sampling is based on a random process which requires the
calculation of random numbers. One can differentiate between n-out-N
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and probabilistic Flow sampling.
5.2.2.1. n-out-of-N Flow Sampling
In n-out-of-N Sampling, n elements are selected out of the parent
population that consists of N elements. One example would be to
generate n different random numbers in the range [1,N] and select all
Flows that have a Flow position equal to one of the random numbers.
5.2.2.2. Probabilistic Flow Sampling
In probabilistic Sampling, the decision whether or not a Flow is
selected is made in accordance with a predefined selection
probability. For probabilistic Sampling, the Sample Size can vary
for different trials. The selection probability does not necessarily
have to be the same for each Flow. Therefore, a difference is
recognized between uniform probabilistic sampling (with the same
selection probability for all Flows) and non-uniform probabilistic
sampling (where the selection probability can vary for different
Flows). For non-uniform probabilistic Flow Sampling the sampling
probability may be adjusted according to the Flow Record content. An
example would be to increase the selection probability of large
volume Flows over small volume Flows as described in the Smart
Sampling technique [DuLT01].
5.3. Flow-state Dependent Flow Selection
Flow-state Dependent Flow Selection can be a deterministic or random
Intermediate Flow Selection Process based on the Flow Record content
and the Flow state which may be kept additionally for each of the
Flows. External processes may update counters, bounds and timers for
each of the Flow Records and the Intermediate Flow Selection Process
utilises this information for the selection decision. A review of
Flow-state Dependent Flow Selection techniques that aim at the
selection of the most frequent items by keeping additional Flow state
information can be found in [CoHa08]. Flow-state Dependent Flow
Selection can only be applied after packet aggregation, when a packet
has been assigned to a Flow. The Intermediate Flow Selection Process
then decides based upon the Flow state for each Flow if it is kept in
the Flow cache or not. Two Flow-state Dependent Flow Selection
Algorithms are here described:
The frequent algorithm [KaPS03] is a technique that aims at the
selection of all flows that at least exceed a 1/k fraction of the
Observed Packet Stream. The algorithm has only a Flow cache of size
k-1 and each Flow in the cache has an additional counter. The
counter is incremented each time a packet belonging to the Flow in
the Flow cache is observed. In case the observed packet does not
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belong to any Flow all counters are decremented and if any of the
Flow counters has a value of zero the Flow is replaced with a Flow
formed from the new packet.
Lossy counting is a selection technique that identifies all Flows
whose packet count exceeds a certain percentage of the whole observed
packet stream (e.g. 5% of all packets) with a certain estimation
error e. Lossy counting separates the observed packet stream in
windows of size N=1/e, where N is an amount of consecutive packets.
For each observed Flow an additional counter will be held in the Flow
state. The counter is incremented each time a packet belonging to
the Flow is observed and all counters are decremented at the end of
each window and all Flows with a counter of zero are removed from the
Flow cache.
5.4. Flow-state Dependent Packet Selection
Flow-state Dependent Packet Selection is not a Flow selection
technique but a packet selection technique. Nevertheless
configuration and reporting parameters for this technique will be
described in this document. An example is the "Sample and Hold"
algorithm [EsVa01] that tries to prefer large volume Flows in the
selection. When a packet arrives it is selected when a Flow Record
for this packet already exists. In case there is no Flow Record, the
packet is selected by a certain probability that is dependent on the
packet size.
6. Configuration of Flow Selection Techniques
This section describes the configuration parameters of the Flow
selection techniques presented above. It provides the basis for an
information model to be adopted in order to configure the Flow
Selection Process within an IPFIX Device. The actual information
model with the Information Elements (IEs) for the configuration is
described together with the reporting IEs in section 7. The
following table gives an overview of the defined Flow selection
techniques, where they can be applied and what their input parameters
are. Depending on where the Flow selection techniques are applied
different input parameters can be configured.
Overview of Flow Selection Techniques:
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+--------------------+----------------+-----------------------------+
| Location | Selection | Selection Input |
| | Technique | |
+--------------------+----------------+-----------------------------+
| In the Metering | Flow-state | packet sampling |
| Process | Dependent | probabilities, Flow |
| | Packet | Selection State, packet |
| | Selection | properties |
+--------------------+----------------+-----------------------------+
| In the Metering | Property Match | Flow record IEs, Selection |
| Process | Flow Filtering | Interval |
+--------------------+----------------+-----------------------------+
| In the Metering | Hash-based | selection range, Hash |
| Process | Flow Filtering | Function, Flow Key, (seed) |
+--------------------+----------------+-----------------------------+
| In the Metering | Time-based | Flow position (derived from |
| Process | Systematic | arrival time of packets), |
| | Flow Sampling | Flow Selection State |
+--------------------+----------------+-----------------------------+
| In the Metering | Sequence-based | Flow position (derived from |
| Process | Systematic | packet position), Flow |
| | Flow Sampling | Selection State |
+--------------------+----------------+-----------------------------+
| In the Metering | Random Flow | random number generator or |
| Process | Sampling | list and packet position, |
| | | Flow state |
+--------------------+----------------+-----------------------------+
| In the Exporting | Property Match | Flow Record content, filter |
| Process/ within | Flow Filtering | function |
| the IPFIX Mediator | | |
+--------------------+----------------+-----------------------------+
| In the Exporting | Hash-based | selection range, Hash |
| Process/ within | Flow Filtering | Function, hash input (Flow |
| the IPFIX Mediator | | Keys and other Flow |
| | | properties) |
+--------------------+----------------+-----------------------------+
| In the Exporting | Flow-state | Flow state parameters, |
| Process/ within | Dependent Flow | random number generator or |
| the IPFIX Mediator | Selection | list |
+--------------------+----------------+-----------------------------+
| In the Exporting | Time-based | Flow arrival time, Flow |
| Process/ within | Systematic | state |
| the IPFIX Mediator | Flow Sampling | |
+--------------------+----------------+-----------------------------+
| In the Exporting | Sequence-based | Flow position, Flow state |
| Process/ within | Systematic | |
| the IPFIX Mediator | Flow Sampling | |
+--------------------+----------------+-----------------------------+
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+--------------------+----------------+-----------------------------+
| In the Exporting | Random Flow | random number generator or |
| Process/ within | Sampling | list and Flow position, |
| the IPFIX Mediator | | Flow state |
+--------------------+----------------+-----------------------------+
Table 1: Overview of Flow Selection Techniques
6.1. Intermediate Flow Selection Process Parameters
This section defines what parameters are required to describe the
most common Flow selection techniques.
Intermediate Flow Selection Process Parameters:
For Property Match Filtering:
- Information Element as specified in [iana-ipfix-assignments]):
Specifies the Information Element which is used as the property
in the filter expression.
- Selection Value or Value Interval:
Specifies the value or interval of the filter expression.
Packets and Flow Records that have a value equal to the Selection
Value or within the Interval will be selected.
For Hash-based Flow Filtering:
- Hash Domain:
Specifies the bits from the packet or Flow which are taken as the
hash input to the Hash Function.
- Hash Function:
Specifies the name of the Hash Function that is used to calculate
the hash value. Possible Hash Functions are BOB [RFC5475], IPSX
[RFC5475], CRC-32 [Bra75]
- Hash Selection Range:
Flows that have a hash value within the Hash Selection Range are
selected. The Hash Selection Range can be a value interval or
arbitrary hash values within the Hash Range of the Hash Function.
- Random Seed or Initializer Value:
Some Hash Functions require an initializing value. In order to
make the selection decision more secure one can choose a random
seed that configures the hash function.
For Flow-state Dependent Flow Selection:
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- frequency threshold:
Specifies the frequency threshold s for Flow-state Dependent Flow
Selection techniques that try to find the most frequent items
within a dataset. All Flows which exceed the defined threshold
will be selected.
- accuracy parameter:
specifies the accuracy parameter e for techniques that deal with
the frequent items problems. The accuracy parameter defines the
maximum error, i.e. no Flows that have a true frequency less than
( s - e) N are selected, where s is the frequency threshold and N
is the total number of packets.
The above list of parameters for Flow-state Dependent Flow Selection
techniques is suitable for the presented frequent item and lossy
counting algorithms. Nevertheless a variety of techniques exist with
very specific parameters which are not defined here.
For Systematic time-based Flow Sampling:
- Interval length (in usec)
Defines the length of the sampling interval during which Flows
are selected.
- Spacing (in usec)
The spacing parameter defines the spacing in usec between the end
of one sampling interval and the start of the next succeeding
interval.
For Systematic count-based Flow Sampling:
- Interval length
Defines the number of Flows that are selected within the sampling
interval.
- Spacing
The spacing parameter defines the spacing in number of observed
Flows between the end of one sampling interval and the start of
the next succeeding interval.
For random n-out-of-N Flow Sampling:
- Population Size N
The Population Size N is the number of all Flows in the
Population from which the sample is drawn.
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- Sampling Size n
The sampling size n is the number of Flows that are randomly
drawn from the population N.
For probabilistic Flow Sampling:
- Sampling probability p
The sampling probability p defines the probability by which each
of the observed Flows is selected.
6.2. Description of Flow-state Dependent Packet Selection
The configuration of Flow-state Dependent Packet Selection has not
been described in [RFC5475] therefore the parameters are defined
here:
For Flow-state Dependent Packet Selection:
- packet selection probability per possible Flow state interval
Defines multiple {Flow interval, packet selection probability}
value pairs that configure the sampling probability depending on
the current Flow state.
- additional parameters
For the configuration of Flow-state Dependent Packet Selection
additional parameters or packet properties may be required, e.g.
the packet size ([EsVa01])
7. Information Model for Intermediate Flow Selection Process
Configuration and Reporting
This section specifies the Information Elements (IEs) that MUST be
exported by an Intermediate Flow Selection Process in order to
support the interpretation of measurement results from Flow
measurements. The information is mainly used to report how many
packets and Flows have been observed in total and how many of them
were selected. This helps for instance to calculate the Attained
Selection Fraction (see also [RFC5476]), which is an important
parameter to provide an accuracy statement. The IEs can provide
reporting information about Flow Records, packets or bytes. The
reported metrics are total number of elements and the number of
selected elements. From this the number of dropped elements can be
derived.
List of Flow Selection Information Elements:
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+-----+--------------------------+------+---------------------------+
| ID | Name | ID | Name |
+-----+--------------------------+------+---------------------------+
| 301 | selectionSequenceID | 302 | selectorID |
+-----+--------------------------+------+---------------------------+
| TBD | flowSelectorAlgorithm | 1 | octetDeltaCount |
| 1 | | | |
+-----+--------------------------+------+---------------------------+
| TBD | flowSelectedOctetDeltaCo | 2 | packetDeltaCount |
| 2 | unt | | |
+-----+--------------------------+------+---------------------------+
| TBD | flowSelectedPacketDeltaC | 3 | originalFlowsPresent |
| 3 | ount | | |
+-----+--------------------------+------+---------------------------+
| TBD | flowSelectedFlowDeltaCou | TBD5 | selectorIDTotalFlowsObser |
| 4 | nt | | ved |
+-----+--------------------------+------+---------------------------+
| TBD | selectorIDTotalFlowsSele | TBD7 | samplingFlowInterval |
| 6 | cted | | |
+-----+--------------------------+------+---------------------------+
| TBD | samplingFlowSpacing | 309 | samplingSize |
| 8 | | | |
+-----+--------------------------+------+---------------------------+
| 310 | samplingPopulation | 311 | samplingProbability |
+-----+--------------------------+------+---------------------------+
| TBD | flowSamplingTimeInterval | TBD1 | flowSamplingTimeSpacing |
| 9 | | 0 | |
+-----+--------------------------+------+---------------------------+
| 326 | digestHashValue | TBD1 | hashFlowDomain |
| | | 1 | |
+-----+--------------------------+------+---------------------------+
| 329 | hashOutputRangeMin | 330 | hashOutputRangeMax |
+-----+--------------------------+------+---------------------------+
| 331 | hashSelectedRangeMin | 332 | hashSelectedRangeMax |
+-----+--------------------------+------+---------------------------+
| 333 | hashDigestOutput | 334 | hashInitialiserValue |
+-----+--------------------------+------+---------------------------+
| 320 | absoluteError | 321 | relativeError |
+-----+--------------------------+------+---------------------------+
| 336 | upperCILimit | 337 | lowerCILimit |
+-----+--------------------------+------+---------------------------+
| 338 | confidenceLevel | | |
+-----+--------------------------+------+---------------------------+
Table 2: Flow Selection Information Elements
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7.1. flowSelectorAlgorithm
Description:
This Information Element identifies the Flow selection
technique(e.g., Filtering, Sampling) that is applied by the
Intermediate Flow Selection Process. Most of these techniques
have parameters as decribed in Section 6. Further technique
identifiers may be added to the list below. It might be necessary
to define new Information Elements to specify their parameters.
The flowSelectorAlgorithm registry is maintained by IANA. New
assignments for the registry will be administered by IANA and are
subject to Expert Review [RFC5226]. The registry can be updated
when specifications of the new technique(s) and any new
Information Elements are provided.
+----+------------------------+--------------------------+
| ID | Technique | Parameters |
+----+------------------------+--------------------------+
| 1 | Systematic count-based | flowSamplingInterval |
| | Sampling | flowSamplingSpacing |
+----+------------------------+--------------------------+
| 2 | Systematic time-based | flowSamplingTimeInterval |
| | Sampling | flowSamplingTimeSpacing |
+----+------------------------+--------------------------+
| 3 | Random n-out-of-N | samplingSize |
| | Sampling | samplingPopulation |
+----+------------------------+--------------------------+
| 4 | Uniform probabilistic | samplingProbability |
| | Sampling | |
+----+------------------------+--------------------------+
| 5 | Property Match | Information Element |
| | Filtering | Value Range |
+----+------------------------+--------------------------+
| Hash-based Filtering | hashInitialiserValue |
+----+------------------------+ hashFlowDomain |
| 6 | using BOB | hashSelectedRangeMin |
+----+------------------------+ hashSelectedRangeMax |
| 7 | using IPSX | hashOutputRangeMin |
+----+------------------------+ hashOutputRangeMax |
| 8 | using CRC | |
+----+------------------------+--------------------------+
| 9 | Flow-state Dependent | No agreed Parameters |
| | Flow Selection | |
+----+------------------------+--------------------------+
Flow Selection Techniques
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Abstract Data Type: unsigned16
ElementId: TBD1
Data Type Semantics: identifier
Status: Proposed
7.2. flowSelectedOctetDeltaCount
Description:
This Information Element specifies the volume in octets of all
Flows that are selected in the Intermediate Flow Selection Process
since the previous report.
Abstract Data Type: unsigned64
ElementId: TBD2
Units: Octets
Status: Proposed
7.3. flowSelectedPacketDeltaCount
Description:
This Information Element specifies the volume in packets of all
Flows that were selected in the Intermediate Flow Selection
Process since the previous report.
Abstract Data Type: unsigned64
ElementId: TBD3
Units: Packets
Status: Proposed
7.4. flowSelectedFlowDeltaCount
Description:
This Information Element specifies the number of Flows that were
selected in the Intermediate Flow Selection Process since the last
report.
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Abstract Data Type: unsigned64
ElementId: TBD4
Units: Flows
Status: Proposed
7.5. selectorIDTotalFlowsObserved
Description:
This Information Element specifies the total number of Flows
observed by a Selector, for a specific value of SelectorId. This
Information Element should be used in an Options Template scoped
to the observation to which it refers. See Section 3.4.2.1 of the
IPFIX protocol document [RFC5101] .
Abstract Data Type: unsigned64
ElementId: TBD5
Units: Flows
Status: Proposed
7.6. selectorIDTotalFlowsSelected
Description:
This Information Element specifies the total number of Flows
selected by a Selector, for a specific value of SelectorId. This
Information Element should be used in an Options Template scoped
to the observation to which it refers. See Section 3.4.2.1 of the
IPFIX protocol document [RFC5101].
Abstract Data Type: unsigned64
ElementId: TBD6
Units: Flows
Status: Proposed
7.7. samplingFlowInterval
Description:
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This Information Element specifies the number of Flows that are
consecutively sampled. A value of 100 means that 100 consecutive
Flows are sampled. For example, this Information Element may be
used to describe the configuration of a systematic count-based
Sampling Selector.
Abstract Data Type: unsigned64
ElementId: TBD7
Units: Flows
Status: Proposed
7.8. samplingFlowSpacing
Description:
This Information Element specifies the number of Flows between two
"samplingFlowInterval"s. A value of 100 means that the next
interval starts 100 Flows (which are not sampled) after the
current "samplingFlowInterval" is over. For example, this
Information Element may be used to describe the configuration of a
systematic count-based Sampling Selector.
Abstract Data Type: unsigned64
ElementId: TBD8
Units: Flows
Status: Proposed
7.9. flowSamplingTimeInterval
Description:
This Information Element specifies the time interval in
microseconds during which all arriving Flows are sampled. For
example, this Information Element may be used to describe the
configuration of a systematic time-based Sampling Selector.
Abstract Data Type: unsigned64
ElementId: TBD9
Units: microseconds
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Status: Proposed
7.10. flowSamplingTimeSpacing
Description:
This Information Element specifies the time interval in
microseconds between two "flowSamplingTimeInterval"s. A value of
100 means that the next interval starts 100 microseconds (during
which no Flows are sampled) after the current
"flowsamplingTimeInterval" is over. For example, this Information
Element may used to describe the configuration of a systematic
time-based Sampling Selector.
Abstract Data Type: unsigned64
ElementId: TBD10
Units: microseconds
Status: Proposed
7.11. hashFlowDomain
Description:
This Information Element specifies the Information Elements that
are used by the Hash-based Flow Selection Selector as the Hash
Domain.
Abstract Data Type: unsigned16
ElementId: TBD11
Data Type Semantics: identifier
Status: Proposed
8. IANA Considerations
8.1. Registration of Information Elements
IANA will register the following IEs in the IPFIX Information
Elements registry at http://www.iana.org/assignments/ipfix/ipfix.xml:
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+-----+----------------+--------+---------+-------+-----------------+
| Val | Name | Data | Data | Statu | Description |
| ue | | Type | Type | s | |
| | | | Semanti | | |
| | | | cs | | |
+-----+----------------+--------+---------+-------+-----------------+
| 1 | flowSelectorAl | unsign | identif | Propo | This |
| | gorithm | ed16 | ier | sed | Information |
| | | | | | Element |
| | | | | | identifies the |
| | | | | | Flow selection |
| | | | | | technique(e.g., |
| | | | | | Filtering, |
| | | | | | Sampling) that |
| | | | | | is applied by |
| | | | | | the |
| | | | | | Intermediate |
| | | | | | Flow Selection |
| | | | | | Process |
+-----+----------------+--------+---------+-------+-----------------+
| 2 | flowSelectedOc | unsign | Octets | Propo | This |
| | tetDeltaCount | ed64 | | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | volume in |
| | | | | | octets of all |
| | | | | | Flows that are |
| | | | | | selected in the |
| | | | | | Intermediate |
| | | | | | Flow Selection |
| | | | | | Process since |
| | | | | | the previous |
| | | | | | report. |
+-----+----------------+--------+---------+-------+-----------------+
| 3 | flowSelectedPa | unsign | Packets | Propo | This |
| | cketDeltaCount | ed64 | | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | volume in |
| | | | | | packets of all |
| | | | | | Flows that were |
| | | | | | selected in the |
| | | | | | Intermediate |
| | | | | | Flow Selection |
| | | | | | Process since |
| | | | | | the previous |
| | | | | | report. |
+-----+----------------+--------+---------+-------+-----------------+
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+-----+----------------+--------+---------+-------+-----------------+
| 4 | flowSelectedFl | unsign | Flows | Propo | This |
| | owDeltaCount | ed64 | | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | number of Flows |
| | | | | | that were |
| | | | | | selected in the |
| | | | | | Intermediate |
| | | | | | Flow Selection |
| | | | | | Process since |
| | | | | | the last |
| | | | | | report. |
+-----+----------------+--------+---------+-------+-----------------+
| 5 | selectorIDTota | unsign | Flows | Propo | This |
| | lFlowsObserved | ed64 | | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | total number of |
| | | | | | Flows observed |
| | | | | | by a Selector, |
| | | | | | for a specific |
| | | | | | value of |
| | | | | | SelectorId. |
| | | | | | This |
| | | | | | Information |
| | | | | | Element should |
| | | | | | be used in an |
| | | | | | Options |
| | | | | | Template scoped |
| | | | | | to the |
| | | | | | observation to |
| | | | | | which it |
| | | | | | refers. See |
| | | | | | Section 3.4.2.1 |
| | | | | | of the IPFIX |
| | | | | | protocol |
| | | | | | document |
| | | | | | [RFC5101] |
+-----+----------------+--------+---------+-------+-----------------+
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+-----+----------------+--------+---------+-------+-----------------+
| 6 | selectorIDTota | unsign | Flows | Propo | This |
| | lFlowsSelected | ed64 | | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | total number of |
| | | | | | Flows selected |
| | | | | | by a Selector, |
| | | | | | for a specific |
| | | | | | value of |
| | | | | | SelectorId. |
| | | | | | This |
| | | | | | Information |
| | | | | | Element should |
| | | | | | be used in an |
| | | | | | Options |
| | | | | | Template scoped |
| | | | | | to the |
| | | | | | observation to |
| | | | | | which it |
| | | | | | refers. See |
| | | | | | Section 3.4.2.1 |
| | | | | | of the IPFIX |
| | | | | | protocol |
| | | | | | document |
| | | | | | [RFC5101]. |
+-----+----------------+--------+---------+-------+-----------------+
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+-----+----------------+--------+---------+-------+-----------------+
| 7 | samplingFlowIn | unsign | Flows | Propo | This |
| | terval | ed64 | | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | number of Flows |
| | | | | | that are |
| | | | | | consecutively |
| | | | | | sampled. A |
| | | | | | value of 100 |
| | | | | | means that 100 |
| | | | | | consecutive |
| | | | | | Flows are |
| | | | | | sampled. For |
| | | | | | example, this |
| | | | | | Information |
| | | | | | Element may be |
| | | | | | used to |
| | | | | | describe the |
| | | | | | configuration |
| | | | | | of a systematic |
| | | | | | count-based |
| | | | | | Sampling |
| | | | | | Selector. |
+-----+----------------+--------+---------+-------+-----------------+
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+-----+----------------+--------+---------+-------+-----------------+
| 8 | samplingFlowSp | unsign | Flows | Propo | This |
| | acing | ed64 | | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | number of Flows |
| | | | | | between two |
| | | | | | "samplingFlowIn |
| | | | | | terval"s. A |
| | | | | | value of 100 |
| | | | | | means that the |
| | | | | | next interval |
| | | | | | starts 100 |
| | | | | | Flows (which |
| | | | | | are not |
| | | | | | sampled) after |
| | | | | | the current |
| | | | | | "samplingFlowI |
| | | | | | nterval" is ove |
| | | | | | r.For example, |
| | | | | | this |
| | | | | | Information |
| | | | | | Element may b |
| | | | | | e used to |
| | | | | | describe the |
| | | | | | configuration |
| | | | | | of a systemat |
| | | | | | iccount-based |
| | | | | | Sampling |
| | | | | | Selector. |
+-----+----------------+--------+---------+-------+-----------------+
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+-----+----------------+--------+---------+-------+-----------------+
| 9 | flowSamplingTi | unsign | microse | Propo | This |
| | meInterval | ed64 | conds | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | time interval |
| | | | | | in microseconds |
| | | | | | during which |
| | | | | | all arriving |
| | | | | | Flows are |
| | | | | | sampled. For |
| | | | | | example, this |
| | | | | | Information |
| | | | | | Element may be |
| | | | | | used to |
| | | | | | describe the |
| | | | | | configuration |
| | | | | | of a systematic |
| | | | | | time-based |
| | | | | | Sampling |
| | | | | | Selector. |
+-----+----------------+--------+---------+-------+-----------------+
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+-----+----------------+--------+---------+-------+-----------------+
| 10 | flowSamplingTi | unsign | microse | Propo | This |
| | meSpacing | ed64 | conds | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | time interval |
| | | | | | in microseconds |
| | | | | | between two |
| | | | | | "flowSamplingTi |
| | | | | | meInterval"s. |
| | | | | | Avalue of 100 |
| | | | | | means that the |
| | | | | | next interval |
| | | | | | starts 100 |
| | | | | | microseconds |
| | | | | | (during which |
| | | | | | no Flows are |
| | | | | | sampled) after |
| | | | | | the current |
| | | | | | "flowsamplingT |
| | | | | | imeInterval" is |
| | | | | | over. For |
| | | | | | example, this |
| | | | | | Information |
| | | | | | Element may |
| | | | | | used to |
| | | | | | describe the |
| | | | | | configuration |
| | | | | | of a systemat |
| | | | | | ictime-based |
| | | | | | Sampling |
| | | | | | Selector. |
+-----+----------------+--------+---------+-------+-----------------+
| 11 | hashFlowDomain | unsign | identif | Propo | This |
| | | ed16 | ier | sed | Information |
| | | | | | Element |
| | | | | | specifies the |
| | | | | | Information |
| | | | | | Elements that |
| | | | | | are used by the |
| | | | | | Hash-based Flow |
| | | | | | Selection |
| | | | | | Selector as the |
| | | | | | Hash Domain. |
+-----+----------------+--------+---------+-------+-----------------+
Table 3: Information Elements to be registered
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8.2. Registration of Object Identifier
IANA will register the following OID in the IPFIX-SELECTOR-MIB
Functions sub-registry at http://www.iana.org/assignments/smi-numbers
according to the procedures set forth in [RFC5815]
+---------+-----------------------+---------------------+-----------+
| Decimal | Name | Description | Reference |
+---------+-----------------------+---------------------+-----------+
| | flowSelectorAlgorithm | This Object | [RFCyyyy] |
| | | Identifier | |
| | | identifies the Flow | |
| | | selection technique | |
| | | (e.g., Filtering, | |
| | | Sampling) that is | |
| | | applied by the Flow | |
| | | Selection Process | |
+---------+-----------------------+---------------------+-----------+
Table 4: Object Identifiers to be registered
Editor's Note (to be removed prior to publication): the RFC editor is
asked to replace "yyyy" in this document by the number of the RFC
when the assignment has been made.
9. Security Considerations
Some of the described flow selection techniques (e.g., flow sampling,
hash-based flow filtering) aim at the selection of a representative
subset of flows in order to estimate parameters of the population.
An adversary may have incentives to influence the selection of flows,
for example to circumvent accounting or to avoid the detection of
packets that are part of an attack.
Security considerations concerning the choice of a Hash Function for
Hash-based Packet Selection have been discussed in Section 6.2.3 of
[RFC5475] and are also appropriate for Hash-based Flow Selection.
[RFC5475] discusses the possibility to craft Packet Streams which are
disproportionately selected or can be used to discover Hash Function
parameters. It also describes vulnerabilities of different Hash
Functions to these attacks, and practices to minimize these
vulnerabilities.
For other sampling approaches a user can gain knowledge about the
start and stop triggers in time-based systematic Sampling, e.g., by
sending test packets. This knowledge might allow users to modify
their send schedule in a way that their packets are
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disproportionately selected or not selected. For random Sampling, a
cryptographically strong random number generator should be used in
order to prevent that an advisory can predict the selection decision
[GoRe08].
Further security threats can occur when Flow Selection parameters are
configured or communicated to other entities. The protocol(s) for
the configuration and reporting of Flow Selection parameters are out
of scope of this document. Nevertheless, a set of initial
requirements for future configuration and reporting protocols are
stated below:
1. Protection against disclosure of configuration information: Flow
Selection configuration information describes the Intermediate
Flow Selection Process and its parameters. This information can
be useful to attackers. Attackers may craft packets that never
fit the selection criteria in order to prevent Flows to be seen
by the Intermediate Flow Selection Process. They can also craft
a lot of packets that fit the selection criteria and overload or
bias subsequent processes. Therefore any transmission of
configuration data (e.g., to configure a process or to report its
actual status) should be protected by encryption.
2. Protection against modification of configuration information: if
wrong configuration information is sent to the Intermediate Flow
Selection Process, it can lead to a malfunction of the
Intermediate Flow Selection Process. Also if wrong configuration
information is reported from the Flow Selection Process to other
processes it can lead to wrong estimations at subsequent
processes. Therefore any protocol that transmits configuration
information should prevent that an attacker can modify
configuration information. Data integrity can be achieved by
authenticating the data.
3. Protection against malicious nodes sending configuration
information: The remote configuration of Flow Selection
techniques should be protected against access by unauthorized
nodes. This can be achieved by access control lists at the
device that hosts the Flow Selection Process (e.g. IPFIX
Exporter, IPFIX Mediator or IPFIX Collector) and by source
authentication. The reporting of configuration data from an
Intermediate Flow Selection Process has to be protected in the
same way. That means that also protocols that report
configuration data from the Intermediate Flow Selection Process
to other processes need to protect against unauthorized nodes
reporting configuration information.
The security threats that originate from communicating configuration
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information to and from Intermediate Flow Selection Processes cannot
be assessed solely with the information given in this document. A
further more detailed assessment of security threats is necessary
when a specific protocol for the configuration or reporting
configuration data is proposed.
10. Acknowledgments
We would like to thank the IPFIX group, especially Brian Trammell,
Paul Aitken and Benoit Claise for fruitful discussions and for
proofreading the document.
11. References
11.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC5101] Claise, B., "Specification of the IP Flow Information
Export (IPFIX) Protocol for the Exchange of IP Traffic
Flow Information", RFC 5101, January 2008.
[RFC5102] Quittek, J., Bryant, S., Claise, B., Aitken, P., and J.
Meyer, "Information Model for IP Flow Information Export",
RFC 5102, January 2008.
[RFC5475] Zseby, T., Molina, M., Duffield, N., Niccolini, S., and F.
Raspall, "Sampling and Filtering Techniques for IP Packet
Selection", RFC 5475, March 2009.
[RFC5476] Claise, B., Johnson, A., and J. Quittek, "Packet Sampling
(PSAMP) Protocol Specifications", RFC 5476, March 2009.
[RFC5815] Dietz, T., Kobayashi, A., Claise, B., and G. Muenz,
"Definitions of Managed Objects for IP Flow Information
Export", RFC 5815, April 2010.
11.2. Informative References
[Bra75] Brayer, K., "Evaluation of 32 Degree Polynomials in Error
Detection on the SATIN IV Autovon Error Patterns",
National Technical Information Service p.74, August 1975.
[CoHa08] Cormode, G. and M. Hadjieleftheriou, "Finding frequent
items in data streams", Journal, Proceedings of the Very
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Large DataBase Endowment VLDB Endowment, Volume 1 Issue 2,
August 2008, August 2008.
[DuLT01] Duffield, N., Lund, C., and M. Thorup, "Charging from
Sampled Network Usage", ACM Internet Measurement Workshop
IMW 2001, San Francisco, USA, November 2001.
[EsVa01] Estan, C. and G,. Varghese, "New Directions in Traffic
Measurement and Accounting: Focusing on the Elephants,
Ignoring the Mice", ACM SIGCOMM Internet Measurement
Workshop 2001, San Francisco (CA), November 2001.
[GoRe08] Goldberg, S., Xiao, D., Tromer, E., Barak, B., and J.
Rexford, "Path-quality monitoring in the presence of
adversaries", ACM SIGMETRICS ACM SIGMETRICS International
Conference on Measurement and Modeling of Computer
Systems, Annapolis, MD, USA, June 2008.
[KaPS03] Karp, R., Papadimitriou, C., and S. S. Shenker, "A simple
algorithm for finding frequent elements in sets and
bags.", ACM Transactions on Database Systems, Volume 28,
51-55, 2003, March 2003.
[MSZC10] Mai, J., Sridharan, A., Zang, H., and C. Chuah, "Fast
Filtered Sampling", Computer Networks Volume 54, Issue 11,
Pages 1885-1898, ISSN 1389-1286, January 2010.
[MaMo02] Manku, G. and R. Motwani, "Approximate Frequency Counts
over Data Streams", Proceedings of the International
Conference on Very large DataBases (VLDB) pages 346--357,
2002, Hong Kong, China, 2002.
[RFC3917] Quittek, J., Zseby, T., Claise, B., and S. Zander,
"Requirements for IP Flow Information Export (IPFIX)",
RFC 3917, October 2004.
[RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an
IANA Considerations Section in RFCs", BCP 26, RFC 5226,
May 2008.
[RFC5470] Sadasivan, G., Brownlee, N., Claise, B., and J. Quittek,
"Architecture for IP Flow Information Export", RFC 5470,
March 2009.
[RFC6183] Kobayashi, A., Claise, B., Muenz, G., and K. Ishibashi,
"IP Flow Information Export (IPFIX) Mediation: Framework",
RFC 6183, April 2011.
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[iana-ipfix-assignments]
"IP Flow Information Export Information Elements", 2007,
<http://www.iana.org/assignments/ipfix/ipfix.xml>.
Authors' Addresses
Salvatore D'Antonio
University of Napoli "Parthenope"
Centro Direzionale di Napoli Is. C4
Naples 80143
Italy
Phone: +39 081 5476766
Email: salvatore.dantonio@uniparthenope.it
Tanja Zseby
CAIDA/FhG FOKUS
San Diego Supercomputer Center (SDSC)
University of California, San Diego (UCSD)
9500 Gilman Drive
La Jolla CA 92093-0505
USA
Email: tanja@caida.org
Christian Henke
Tektronix Communication Berlin
Wohlrabedamm 32
Berlin 13629
Germany
Phone: +49 17 2323 8717
Email: christian.henke@tektronix.com
Lorenzo Peluso
University of Napoli
Via Claudio 21
Napoli 80125
Italy
Phone: +39 081 7683821
Email: lorenzo.peluso@unina.it
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