Network Working Group                                       C. Popoviciu
Request for Comments: 5180                                      A. Hamza
Category: Informational                                  G. Van de Velde
                                                           Cisco Systems
                                                             D. Dugatkin
                                                           FastSoft Inc.
                                                                May 2008


     IPv6 Benchmarking Methodology for Network Interconnect Devices

Status of This Memo

   This memo provides information for the Internet community.  It does
   not specify an Internet standard of any kind.  Distribution of this
   memo is unlimited.

Abstract

   The benchmarking methodologies defined in RFC 2544 are IP version
   independent.  However, RFC 2544 does not address some of the
   specificities of IPv6.  This document provides additional
   benchmarking guidelines, which in conjunction with RFC 2544, lead to
   a more complete and realistic evaluation of the IPv6 performance of
   network interconnect devices.  IPv6 transition mechanisms are outside
   the scope of this document.

























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Table of Contents

   1. Introduction ....................................................2
   2. Existing Definitions ............................................3
   3. Tests and Results Evaluation ....................................3
   4. Test Environment Setup ..........................................3
   5. Test Traffic ....................................................4
      5.1. Frame Formats and Sizes ....................................4
           5.1.1. Frame Sizes to Be Used on Ethernet ..................5
           5.1.2. Frame Sizes to Be Used on SONET .....................5
      5.2. Protocol Addresses Selection ...............................6
           5.2.1. DUT Protocol Addresses ..............................6
           5.2.2. Test Traffic Protocol Addresses .....................7
      5.3. Traffic with Extension Headers .............................7
      5.4. Traffic Setup ..............................................9
   6. Modifiers .......................................................9
      6.1. Management and Routing Traffic .............................9
      6.2. Filters ...................................................10
           6.2.1. Filter Format ......................................10
           6.2.2. Filter Types .......................................11
   7. Benchmarking Tests .............................................12
      7.1. Throughput ................................................13
      7.2. Latency ...................................................13
      7.3. Frame Loss ................................................13
      7.4. Back-to-Back Frames .......................................13
      7.5. System Recovery ...........................................14
      7.6. Reset .....................................................14
   8. IANA Considerations ............................................14
   9. Security Considerations ........................................14
   10. Conclusions ...................................................15
   11. Acknowledgements ..............................................15
   12. References ....................................................15
      12.1. Normative References .....................................15
      12.2. Informative References ...................................16
   Appendix A.  Theoretical Maximum Frame Rates Reference ............17
      A.1.  Ethernet .................................................17
      A.2.  Packet over SONET ........................................18

1.  Introduction

   The benchmarking methodologies defined by RFC 2544 [9] are proving to
   be useful in consistently evaluating IPv4 forwarding performance of
   network elements.  Adherence to these testing and result analysis
   procedures facilitates objective comparison of IPv4 performance data
   measured on various products and by various individuals.  While the
   principles behind the methodologies introduced in RFC 2544 are
   largely IP version independent, the protocol has continued to evolve,
   particularly in its version 6 (IPv6).



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   This document provides benchmarking methodology recommendations that
   address IPv6-specific aspects, such as evaluating the forwarding
   performance of traffic containing extension headers, as defined in
   RFC 2460 [2].  These recommendations are defined within the RFC 2544
   framework, and they complement the test and result analysis
   procedures as described in RFC 2544.

   The terms used in this document remain consistent with those defined
   in "Benchmarking Terminology for Network Interconnect Devices", RFC
   1242 [7].  This terminology SHOULD be consulted before using or
   applying the recommendations of this document.

   Any methodology aspects not covered in this document SHOULD be
   assumed to be treated based on the RFC 2544 recommendations.

2.  Existing Definitions

   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 BCP 14, RFC 2119 [1].
   RFC 2119 defines the use of these key words to help make the intent
   of standards track documents as clear as possible.  While this
   document uses these key words, this document is not a standards track
   document.

3.  Tests and Results Evaluation

   The recommended performance evaluation tests are described in Section
   7 of this document.  Not all of these tests are applicable to all
   network element types.  Nevertheless, for each evaluated device, it
   is recommended to perform as many of the applicable tests described
   in Section 6 as possible.

   Test execution and results analysis MUST be performed while observing
   generally accepted testing practices regarding repeatability,
   variance, and statistical significance of small numbers of trials.

4.  Test Environment Setup

   The test environment setup options recommended for the IPv6
   performance evaluation are the same as those described in Section 6
   of RFC 2544, in both single-port and multi-port scenarios.
   Single-port testing measures per-interface forwarding performance,
   while multi-port testing measures the scalability of forwarding
   performance across the entire platform.






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   Throughout the test, the Device Under Test (DUT) can be monitored for
   relevant resource (processor, memory, etc.) utilization.  This data
   could be beneficial in understanding traffic processing by each DUT
   and the resources that must be allocated for IPv6.  It could reveal
   if the IPv6 traffic is processed in hardware, by applicable devices,
   under all test conditions, or if it is punted in the software-
   switched path.  If such data is considered of interest, it MUST be
   collected out of band and be independent of any management data
   collected through the interfaces forwarding the test traffic.

   Note: During testing, either static or dynamic options for neighbor
   discovery can be used.  In the static case, the IPv6 neighbor
   information for the test tool is manually configured on the DUT, and
   the IPv6 neighbor information for the DUT is manually configured on
   the test tool.  In the dynamic case, the IPv6 neighbor information is
   dynamically discovered by each device through the neighbor discovery
   protocol.  The static option can be used as long as it is supported
   by the test tool.  The dynamic option is preferred wherein the test
   tool interacts with the DUT for the duration of the test to maintain
   the respective neighbor caches in an active state.  To avoid neighbor
   solicitation (NS) and neighbor advertisement (NA) storms due to the
   neighbor unreachability detection (NUD) mechanism [6], the test
   scenarios assume test traffic simulates end points and IPv6 source
   and destination addresses that are one hop beyond the DUT.

5.  Test Traffic

   Traffic used for all tests described in this document SHOULD meet the
   requirements described in this section.  These requirements are
   designed to reflect the characteristics of IPv6 unicast traffic.
   Using the recommended IPv6 traffic profile leads to a complete
   evaluation of the network element performance.

5.1.  Frame Formats and Sizes

   Two types of media are commonly deployed, and each SHOULD be tested
   if the network element supports that type of media: Ethernet and
   SONET (Synchronous Optical Network).  This section identifies the
   frame sizes that SHOULD be used for each media type.  Refer to
   recommendations in RFC 2544 for all other media types.

   Similar to IPv4, small frame sizes help characterize the per-frame
   processing overhead of the DUT.  Note that the minimum IPv6 packet
   size (40 bytes) is larger than that of an IPv4 packet (20 bytes).
   Tests should compensate for this difference.






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   The frame sizes listed for IPv6 include the extension headers used in
   testing (see Section 5.3).  By definition, extension headers are part
   of the IPv6 packet payload.  Depending on the total length of the
   extension headers, their use might not be possible at the smallest
   frame sizes.

   Note: Test tools commonly use signatures to identify test traffic
   packets to verify that there are no packet drops or out-of-order
   packets, or to calculate various statistics such as delay and jitter.
   This could be the reason why the minimum frame size selectable
   through the test tool might not be as low as the theoretical one
   presented in this document.

5.1.1.  Frame Sizes to Be Used on Ethernet

   Ethernet, in all its types, has become the most commonly deployed
   media in today's networks.  The following frame sizes SHOULD be used
   for benchmarking over this media type: 64, 128, 256, 512, 1024, 1280,
   and 1518 bytes.

   Note: The recommended 1518-byte frame size represents the maximum
   size of an untagged Ethernet frame.  According to the IEEE 802.3as
   standard [13], the frame size can be increased up to 2048 bytes to
   accommodate frame tags and other encapsulation required by the IEEE
   802.1AE MAC [14] security protocol.  A frame size commonly used in
   operational environments is 1522 bytes, the max length for a
   VLAN-tagged frame, as per 802.1D [15].

   Note: While jumbo frames are outside the scope of the 802.3 IEEE
   standard, tests SHOULD be executed with frame sizes selected based on
   the values supported by the device under test.  Examples of commonly
   used jumbo frame sizes are: 4096, 8192, and 9216 bytes.

   The maximum frame rates for each frame size and the various Ethernet
   interface types are provided in Appendix A.

5.1.2.  Frame Sizes to Be Used on SONET

   Packet over SONET (PoS) interfaces are commonly used for edge uplinks
   and high-bandwidth core links.  Evaluating the forwarding performance
   of PoS interfaces supported by the DUT is recommended.  The following
   frame sizes SHOULD be used for this media type: 47, 64, 128, 256,
   512, 1024, 1280, 1518, 2048, 4096 bytes.

   The theoretical maximum frame rates for each frame size and the
   various PoS interface types are provided in Appendix A.





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5.2.  Protocol Addresses Selection

   There are two aspects of IPv6 benchmarking testing where IP address
   selection considerations MUST be analyzed: the selection of IP
   addresses for the DUT and the selection of addresses for test
   traffic.

5.2.1.  DUT Protocol Addresses

   IANA reserved an IPv6 address block for use with IPv6 benchmark
   testing (see Section 8).  It MAY be assumed that addresses in this
   block are not globally routable, and they MUST NOT be used as
   Internet source or destination addresses.

   Similar to Appendix C of RFC 2544, addresses from the first half of
   this range SHOULD be used for the ports viewed as input and addresses
   from the other half of the range for the output ports.

   The prefix length of the IPv6 addresses configured on the DUT
   interfaces MUST fall into either of the following:

      o  Prefix length is /126, which would simulate a point-to-point
         link for a core router.

      o  Prefix length is smaller or equal to /64.

   No prefix lengths SHOULD be selected in the range between 64 and 128
   except the 126 value mentioned above.

   Note that /126 prefixes might not always be the best choice for
   addressing point-to-point links such as back-to-back Ethernet unless
   the auto-provisioning mechanism is disabled.  Also, not all network
   elements support addresses of this prefix length.

   While with IPv6, the DUT interfaces can be configured with multiple
   global unicast addresses, the methodology described in this document
   does not require testing such a scenario.  It is not expected that
   such an evaluation would bring additional data regarding the
   performance of the network element.

   The Interface ID portion of global unicast IPv6 DUT addresses SHOULD
   be set to ::1.  There are no requirements in the selection of the
   Interface ID portion of the link local IPv6 addresses.








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   It is recommended that multiple iterations of the benchmark tests be
   conducted using the following prefix lengths: 48, 64, 126, and 128
   for the advertised traffic destination prefix.  Other prefix lengths
   can be used.  However, the indicated range reflects major prefix
   boundaries expected to be present in IPv6 routing tables, and they
   should be representative to establish baseline performance metrics.

5.2.2.  Test Traffic Protocol Addresses

   IPv6 source and destination addresses for the test streams SHOULD
   belong to the IPv6 range assigned by IANA, as defined in Section 8.
   The source addresses SHOULD belong to one half of the range and the
   destination addresses to the other, reflecting the DUT interface IPv6
   address selection.

   Tests SHOULD first be executed with a single stream leveraging a
   single source-destination address pair.  The tests SHOULD then be
   repeated with traffic using a random destination address in the
   corresponding range.  If the network element prefix lookup
   capabilities are evaluated, the tests SHOULD focus on the IPv6
   relevant prefix boundaries: 0-64, 126, and 128.

   Note: When statically defined neighbors are not used, the parameters
   affecting Neighbor Unreachability Detection should be consistently
   set.  The IPv6 prefix-reachable time in the router advertisement
   SHOULD be set to 30 seconds.

5.3.  Traffic with Extension Headers

   Extension headers are an intrinsic part of the IPv6 architecture [2].
   They are used with various types of practical traffic such as:
   fragmented traffic, mobile IP-based traffic, and authenticated and
   encrypted traffic.  For these reasons, all tests described in this
   document SHOULD be performed with both traffic that has no extension
   headers and traffic that has a set of extension headers.  Extension
   header types can be selected from the following list [2] that
   reflects the recommended order of multiple extension headers in a
   packet:

      o  Hop-by-hop header
      o  Destination options header
      o  Routing header
      o  Fragment header
      o  Authentication header
      o  Encapsulating security payload (ESP) header
      o  Destination options header
      o  Mobility header




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   Since extension headers are an intrinsic part of the protocol and
   they fulfill different roles, benchmarking of traffic containing each
   extension header SHOULD be executed individually.

   The special processing rules for the hop-by-hop extension header
   require a specific benchmarking approach.  Unlike other extension
   headers, this header must be processed by each node that forwards the
   traffic.  Tests with traffic containing these extension header types
   will not measure the forwarding performance of the DUT, but rather
   its extension-header processing capability, which is dependent on the
   information contained in the extension headers.  The concern is that
   this traffic, at high rates, could have a negative impact on the
   operational resources of the router, and it could be used as a
   security threat.  When benchmarking with traffic that contains the
   hop-by-hop extension header, the goal is not to measure throughput
   [9] as in the case of the other extension headers, but rather to
   evaluate the impact of such traffic on the router.  In this case,
   traffic with the hop-by-hop extension headers should be sent at 1%,
   10%, and 50% of the interface total bandwidth.  Device resources must
   be monitored at each traffic rate to determine the impact.

   Tests with traffic containing each individual extension header MUST
   be complemented with tests containing a chain of two or more
   extension headers (the chain MUST NOT contain the hop-by-hop
   extension header).  This chain should also exclude the ESP [5]
   extension header, since traffic with an encrypted payload cannot be
   used in tests with modifiers such as filters based on upper-layer
   information (see Section 5).  Since the DUT is not analyzing the
   content of the extension headers, any combination of extension
   headers can be used in testing.  The extension header chain
   recommended for testing is:

      o  Routing header - 24-32 bytes
      o  Destination options header - 8 bytes
      o  Fragment header - 8 bytes

   This is a real-life extension-header chain that would be found in an
   IPv6 packet between two mobile nodes exchanged over an optimized path
   that requires fragmentation.  The listed extension headers' lengths
   represent test tool defaults.  The total length of the extension
   header chain SHOULD be larger than 32 bytes.

   Extension headers add extra bytes to the payload size of the IP
   packets, which MUST be factored in when used in testing at low frame
   sizes.  Their presence will modify the minimum packet size used in






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   testing.  For direct comparison between the data obtained with
   traffic that has extension headers and with traffic that doesn't have
   them at low frame size, a common value SHOULD be selected for the
   smallest frame size of both types of traffic.

   For most cases, the network elements ignore the extension headers
   when forwarding IPv6 traffic.  For these reasons, it is likely the
   performance impact related to extension headers will be observed only
   when testing the DUT with traffic filters that contain matching
   conditions for the upper-layer protocol information.  In those cases,
   the DUT MUST traverse the chain of extension headers, a process that
   could impact performance.

5.4.  Traffic Setup

   All tests recommended in this document SHOULD be performed with
   bi-directional traffic.  For asymmetric situations, tests MAY be
   performed with uni-directional traffic for a more granular
   characterization of the DUT performance.  In these cases, the
   bi-directional traffic testing would reveal only the lowest
   performance between the two directions.

   All other traffic profile characteristics described in RFC 2544
   SHOULD be applied in this testing as well.  IPv6 multicast
   benchmarking is outside the scope of this document.

6.  Modifiers

   RFC 2544 underlines the importance of evaluating the performance of
   network elements under certain operational conditions.  The
   conditions defined in Section 11 of RFC 2544 are common to IPv4 and
   IPv6, except that IPv6 does not employ layer 2 or 3 broadcast frames.
   IPv6 does not use layer 2 or layer 3 broadcasts.  This section
   provides additional conditions that are specific to IPv6.  The suite
   of tests recommended in this document SHOULD be first executed in the
   absence of these conditions and then repeated under each of these
   conditions separately.

6.1.  Management and Routing Traffic

   The procedures defined in Sections 11.2 and 11.3 of RFC 2544 are
   applicable for IPv6 management and routing update frames as well.









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6.2.  Filters

   The filters defined in Section 11.4 of RFC 2544 apply to IPv6
   benchmarking as well.  The filter definitions must be expanded to
   include upper-layer protocol information matching in order to analyze
   the handling of traffic with extension headers, which are an
   important architectural component of IPv6.

6.2.1.  Filter Format

   The filter format defined in RFC 2544 is applicable to IPv6 as well,
   except that the source addresses (SA) and destination addresses (DA)
   are IPv6 addresses.  In addition to these basic filters, the
   evaluation of IPv6 performance SHOULD analyze the correct filtering
   and handling of traffic with extension headers.

   While the intent is not to evaluate a platform's capability to
   process the various extension header types, the goal is to measure
   performance impact when the network element must parse through the
   extension headers to reach upper-layer information.  In IPv6, routers
   do not have to parse through the extension headers (other than
   hop-by-hop) unless, for example, upper-layer information has to be
   analyzed due to filters.

   To evaluate the network element handling of IPv6 traffic with
   extension headers, the definition of the filters must be extended to
   include conditions applied to upper-layer protocol information.  The
   following filter format SHOULD be used for this type of evaluation:

      [permit|deny]  [protocol] [SA] [DA]

   where permit or deny indicates the action to allow or deny a packet
   through the interface the filter is applied to.  The protocol field
   is defined as:

      o  ipv6: any IP Version 6 traffic

      o  tcp: Transmission Control Protocol

      o  udp: User Datagram Protocol

   and SA stands for the source address and DA for the destination
   address.








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   The upper-layer protocols listed above are a recommended selection.
   However, they do not represent an all-inclusive list of upper-layer
   protocols that could be used in defining filters.  The filters
   described in these benchmarking recommendations apply to native IPv6
   traffic and upper-layer protocols (tcp, udp) transported in native
   IPv6 packets.

6.2.2.  Filter Types

   Based on RFC 2544 recommendations, two types of tests are executed
   when evaluating performance in the presence of modifiers: one with a
   single filter and another with 25 filters.  Examples of recommended
   filters are illustrated using the IPv6 documentation prefix [11]
   2001:DB8::.

   Examples of single filters are:

      Filter for TCP traffic - permit tcp 2001:DB8::1 2001:DB8::2
      Filter for UDP traffic - permit udp 2001:DB8::1 2001:DB8::2
      Filter for IPv6 traffic - permit ipv6 2001:DB8::1 2001:DB8::2

   The single line filter case SHOULD verify that the network element
   permits all TCP/UDP/IPv6 traffic with or without any number of
   extension headers from IPv6 SA 2001:DB8::1 to IPv6 DA 2001:DB8::2 and
   deny all other traffic.

   Example of 25 filters:

      deny tcp 2001:DB8:1::1 2001:DB8:1::2
      deny tcp 2001:DB8:2::1 2001:DB8:2::2
      deny tcp 2001:DB8:3::1 2001:DB8:3::2
      ...
      deny tcp 2001:DB8:C::1 2001:DB8:C::2
      permit tcp 2001:DB8:99::1 2001:DB8:99::2
      deny tcp 2001:DB8:D::1 2001:DB8:D::2
      deny tcp 2001:DB8:E::1 2001:DB8:E::2
      ...
      deny tcp 2001:DB8:19::1 2001:DB8:19::2
      deny ipv6 any any

   The router SHOULD deny all traffic with or without extension headers
   except TCP traffic with SA 2001:DB8:99::1 and DA 2001:DB8:99::2.









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7.  Benchmarking Tests

   This document recommends the same benchmarking tests described in RFC
   2544 while observing the DUT setup and the traffic setup
   considerations described above.  The following sections state the
   test types explicitly, and they highlight only the methodology
   differences that might exist with respect to those described in
   Section 26 of RFC 2544.

   The specificities of IPv6, particularly the definition of extension
   header processing, require additional benchmarking steps.  The tests
   recommended by RFC 2544 MUST be repeated for IPv6 traffic without
   extension headers and for IPv6 traffic with one or multiple extension
   headers.

   IPv6's deployment in existing IPv4 environments and the expected long
   coexistence of the two protocols leads network operators to place
   great emphasis on understanding the performance of platforms
   processing both types of traffic.  While device resources are shared
   between the two protocols, it is important that IPv6-enabled
   platforms not experience degraded IPv4 performance.  Thus, IPv6
   benchmarking SHOULD be performed in the context of a stand-alone
   protocol as well as in the context of its coexistence with IPv4.

   The modifiers defined are independent of the extension header type,
   so they can be applied equally to each one of the above tests.

   The benchmarking tests described in this section SHOULD be performed
   under each of the following conditions:

   Extension header specific conditions:

   i)    IPv6 traffic with no extension headers

   ii)   IPv6 traffic with one extension header from the list in Section
         5.3

   iii)  IPv6 traffic with the chain of extension headers described in
         Section 5.3

   Coexistence-specific conditions:

   iv)   IPv4 ONLY traffic benchmarking

   v)    IPv6 ONLY traffic benchmarking

   vi)   IPv4-IPv6 traffic mix with the ratio 90% vs 10%




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   vii)  IPv4-IPv6 traffic mix with the ratio 50% vs 50%

   viii) IPv4-IPv6 traffic mix with the ratio 10% vs 90%

   Combining the test conditions listed for benchmarking IPv6 as a
   stand-alone protocol and the coexistence tests leads to a
   large-coverage matrix.  At a minimum requirement, the coexistence
   tests should use IPv6 traffic with no extension headers and the 10%-
   90%, 90%-10%, or IPv4/IPv6 traffic mix.

   The subsequent sections each describe specific tests that MUST be
   executed under the conditions listed above for a complete
   benchmarking of IPv6-forwarding performance.

7.1.  Throughput

   Objective: To determine the DUT throughput as defined in RFC 1242.

   Procedure: Same as RFC 2544.

   Reporting Format: Same as RFC 2544.

7.2.  Latency

   Objective: To determine the latency as defined in RFC 1242.

   Procedure: Same as RFC 2544.

   Reporting Format: Same as RFC 2544.

7.3.  Frame Loss

   Objective: To determine the frame-loss rate (as defined in RFC 1242)
   of a DUT throughout the entire range of input data rates and frame
   sizes.

   Procedure: Same as RFC 2544.

   Reporting Format: Same as RFC 2544.

7.4.  Back-to-Back Frames

   Based on the IPv4 experience, the back-to-back frames test is
   characterized by significant variance due to short-term variations in
   the processing flow.  For these reasons, this test is no longer
   recommended for IPv6 benchmarking.





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7.5.  System Recovery

   Objective: To characterize the speed at which a DUT recovers from an
   overload condition.

   Procedure: Same as RFC 2544.

   Reporting Format: Same as RFC 2544.

7.6.  Reset

   Objective: To characterize the speed at which a DUT recovers from a
   device or software reset.

   Procedure: Same as RFC 2544.

   Reporting Format: Same as RFC 2544.

8.  IANA Considerations

   The IANA has allocated 2001:0200::/48 for IPv6 benchmarking, which is
   a 48-bit prefix from the RFC 4773 pool.  This allocation is similar
   to 198.18.0.0/15, defined in RFC 3330 [10].  This prefix length (48)
   provides similar flexibility as the range allocated for IPv4
   benchmarking, and it takes into consideration address conservation
   and simplicity of usage concerns.  The requested size meets the
   requirements for testing large network elements and large emulated
   networks.

   Note: Similar to RFC 2544 avoiding the use of RFC 1918 address space
   for benchmarking tests, this document does not recommend the use of
   RFC 4193 [4] (Unique Local Addresses) in order to minimize the
   possibility of conflicts with operational traffic.

9.  Security Considerations

   Benchmarking activities, as described in this memo, are limited to
   technology characterization using controlled stimuli in a laboratory
   environment, with dedicated address space and the constraints
   specified in the sections above.

   The benchmarking network topology will be an independent test setup
   and MUST NOT be connected to devices that may forward the test
   traffic into a production network or misroute traffic to the test
   management network.






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   Further, benchmarking is performed on a "black-box" basis, relying
   solely on measurements observable external to the DUT/SUT (System
   Under Test).

   Special capabilities SHOULD NOT exist in the DUT/SUT specifically for
   benchmarking purposes.  Any implications for network security arising
   from the DUT/SUT SHOULD be identical in the lab and in production
   networks.

   The isolated nature of the benchmarking environments and the fact
   that no special features or capabilities, other than those used in
   operational networks, are enabled on the DUT/SUT requires no security
   considerations specific to the benchmarking process.

10.  Conclusions

   The Benchmarking Methodology for Network Interconnect Devices
   document, RFC 2544 [9], is for the most part applicable to evaluating
   the IPv6 performance of network elements.  This document addresses
   the IPv6-specific requirements that MUST be observed when applying
   the recommendations of RFC 2544.  These additional requirements stem
   from the architecture characteristics of IPv6.  This document is not
   a replacement for, but a complement to, RFC 2544.

11.  Acknowledgements

   Scott Bradner provided valuable guidance and recommendations for this
   document.  The authors acknowledge the work done by Cynthia Martin
   and Jeff Dunn with respect to defining the terminology for IPv6
   benchmarking.  The authors would like to thank Bill Kine for his
   contribution to the initial document and to Tom Alexander, Bill
   Cerveny, Silvija Dry, Sven Lanckmans, Dean Lee, Athanassios
   Liakopoulos, Benoit Lourdelet, Al Morton, David Newman, Rajiv
   Papejna, Dan Romascanu, and Pekka Savola for their very helpful
   feedback.  Maryam Hamza inspired the authors to complete this
   document.

12.  References

12.1.  Normative References

   [1]   Bradner, S., "Key words for use in RFCs to Indicate Requirement
         Levels", BCP 14, RFC 2119, March 1997.

   [2]   Deering, S. and R. Hinden, "Internet Protocol, Version 6 (IPv6)
         Specification", RFC 2460, December 1998.





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RFC 5180             IPv6 Benchmarking Methodology              May 2008


   [3]   Malis, A. and W. Simpson, "PPP over SONET/SDH", RFC 2615, June
         1999.

   [4]   Hinden, R. and B. Haberman, "Unique Local IPv6 Unicast
         Addresses", RFC 4193, October 2005.

   [5]   Kent, S., "IP Encapsulating Security Payload (ESP)", RFC 4303,
         December 2005.

   [6]   Narten, T., Nordmark, E., Simpson, W., and H. Soliman,
         "Neighbor Discovery for IP version 6 (IPv6)", RFC 4861,
         September 2007.

12.2.  Informative References

   [7]   Bradner, S., "Benchmarking Terminology for Network
         Interconnection Devices", RFC 1242, July 1991.

   [8]   Simpson, W., Ed., "PPP in HDLC-like Framing", STD 51, RFC 1662,
         July 1994.

   [9]   Bradner, S. and J. McQuaid, "Benchmarking Methodology for
         Network Interconnect Devices", RFC 2544, March 1999.

   [10]  IANA, "Special-Use IPv4 Addresses", RFC 3330, September 2002.

   [11]  Huston, G., Lord, A., and P. Smith, "IPv6 Address Prefix
         Reserved for Documentation", RFC 3849, July 2004.

   [12]  Newman, D. and T. Player, "Hash and Stuffing: Overlooked
         Factors in Network Device Benchmarking", RFC 4814, March 2007.

   [13]  LAN/MAN Standards Committee of the IEEE Computer Society, "IEEE
         Std 802.3as-2006, Part 3: Carrier Sense Multiple Access with
         Collision Detection (CSMA/CD) Access Method and Physical Layer
         Specifications, Amendment 3: Frame format extensions", November
         2006.

   [14]  Allyn Romanow (editor), "IEEE Std 802.3ae, Media Access Control
         (MAC) Security", June 2006.

   [15]  Mick Seaman (editor), "IEEE Std 802.1D-2004, MAC Bridges",
         February 2004.








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Appendix A.  Theoretical Maximum Frame Rates Reference

   This appendix provides the formulas to calculate and the values for
   the theoretical maximum frame rates for two media types: Ethernet and
   SONET.

A.1.  Ethernet

   The throughput in frames per second (fps) for various Ethernet
   interface types and for a frame size X can be calculated with the
   following formula:

             Line Rate (bps)
      ------------------------------
      (8bits/byte)*(X+20)bytes/frame

   The 20 bytes in the formula is the sum of the preamble (8 bytes) and
   the inter-frame gap (12 bytes).  The throughput for various Ethernet
   interface types and frame sizes:

      Size     10Mb/s   100Mb/s    1000Mb/s     10000Mb/s
      Bytes    pps      pps        pps          pps

      64       14,880   148,809    1,488,095    14,880,952
      128      8,445    84,459     844,594      8,445,945
      256      4,528    45,289     452,898      4,528,985
      512      2,349    23,496     234,962      2,349,624
      1024     1,197    11,973     119,731      1,197,318
      1280     961      9,615      96,153       961,538
      1518     812      8,127      81,274       812,743
      1522     810      8,106      81,063       810,635
      2048     604      6,044      60,444       604,448
      4096     303      3,036      30,396       303,691
      8192     152      1,522      15,221       152,216
      9216     135      1,353      13,534       135,339

   Note: Ethernet's maximum frame rates are subject to variances due to
   clock slop.  The listed rates are theoretical maximums, and actual
   tests should account for a +/- 100 ppm tolerance.












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A.2.  Packet over SONET

   ANSI T1.105 SONET provides the formula for calculating the maximum
   available bandwidth for the various Packet over SONET (PoS) interface
   types:

      STS-Nc (N = 3Y, where Y=1,2,3,etc)

      [(N*87) - N/3]*(9 rows)*(8 bit/byte)*(8000 frames/sec)

   Packets over SONET can use various encapsulations: PPP [3], High-
   Level Data Link Control (HDLC) [8], and Frame Relay.  All these
   encapsulations use a 4-byte header, a 2- or 4-byte Frame Check
   Sequence (FCS) field, and a 1-byte Flag that are all accounted for in
   the overall frame size.  The maximum frame rate for various interface
   types can be calculated with the formula (where X represents the
   frame size in bytes):

             Line Rate (bps)
      ------------------------------
      (8bits/byte)*(X+1)bytes/frame

   The theoretical maximum frame rates for various PoS interface types
   and frame sizes:

      Size   OC-3c    OC-12c     OC-48c     OC-192c     OC-768c
      Bytes  fps      fps        fps        fps         fps

      47     390,000  1,560,000  6,240,000  24,960,000  99,840,000
      64     288,000  1,152,000  4,608,000  18,432,000  73,728,000
      128    145,116  580,465    2,321,860  9,287,441   37,149,767
      256    72,840   291,361    1,165,447  4,661,789   18,647,159
      512    36,491   145,964    583,859    2,335,438   9,341,754
      1024   18,263   73,053     292,214    1,168,858   4,675,434
      2048   9,136    36,544     146,178    584,714     2,338,857
      4096   4,569    18,276     73,107     292,428     1,169,714

   It is important to note that throughput test results may vary from
   the values presented in Appendices A.1 and A.2 due to bit stuffing
   performed by various media types [12].  The theoretical throughput
   numbers were rounded down.










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RFC 5180             IPv6 Benchmarking Methodology              May 2008


Authors' Addresses

   Ciprian Popoviciu
   Cisco Systems
   Kit Creek Road
   RTP, North Carolina  27709
   USA

   Phone: 919 787 8162
   EMail: cpopovic@cisco.com


   Ahmed Hamza
   Cisco Systems
   3000 Innovation Drive
   Kanata  K2K 3E8
   Canada

   Phone: 613 254 3656
   EMail: ahamza@cisco.com


   Gunter Van de Velde
   Cisco Systems
   De Kleetlaan 6a
   Diegem  1831
   Belgium

   Phone: +32 2704 5473
   EMail: gunter@cisco.com


   Diego Dugatkin
   FastSoft, Inc.
   150 S. Los Robles Ave.
   Pasadena, CA 91101
   USA

   Phone: +1-626-357-7012
   EMail: diego@fastsoft.com











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Full Copyright Statement

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