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Internet Engineering Task Force (IETF) M. Georgescu Request for Comments: 8219 L. Pislaru Category: Informational RCS&RDS ISSN: 2070-1721 G. Lencse Szechenyi Istvan University August 2017 Benchmarking Methodology for IPv6 Transition Technologies Abstract Benchmarking methodologies that address the performance of network interconnect devices that are IPv4- or IPv6-capable exist, but the IPv6 transition technologies are outside of their scope. This document provides complementary guidelines for evaluating the performance of IPv6 transition technologies. More specifically, this document targets IPv6 transition technologies that employ encapsulation or translation mechanisms, as dual-stack nodes can be tested using the recommendations of RFCs 2544 and 5180. The methodology also includes a metric for benchmarking load scalability. Status of This Memo This document is not an Internet Standards Track specification; it is published for informational purposes. This document is a product of the Internet Engineering Task Force (IETF). It represents the consensus of the IETF community. It has received public review and has been approved for publication by the Internet Engineering Steering Group (IESG). Not all documents approved by the IESG are a candidate for any level of Internet Standard; see Section 2 of RFC 7841. Information about the current status of this document, any errata, and how to provide feedback on it may be obtained at http://www.rfc-editor.org/info/rfc8219. Georgescu, et al. Informational [Page 1] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 Copyright Notice Copyright (c) 2017 IETF Trust and the persons identified as the document authors. All rights reserved. This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License. Georgescu, et al. Informational [Page 2] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 Table of Contents 1. Introduction ....................................................4 1.1. IPv6 Transition Technologies ...............................4 2. Conventions Used in This Document ...............................6 3. Terminology .....................................................7 4. Test Setup ......................................................7 4.1. Single-Translation Transition Technologies .................8 4.2. Encapsulation and Double-Translation Transition Technologies ...............................................8 5. Test Traffic ....................................................9 5.1. Frame Formats and Sizes ....................................9 5.1.1. Frame Sizes to Be Used over Ethernet ...............10 5.2. Protocol Addresses ........................................10 5.3. Traffic Setup .............................................10 6. Modifiers ......................................................11 7. Benchmarking Tests .............................................11 7.1. Throughput ................................................11 7.2. Latency ...................................................11 7.3. Packet Delay Variation ....................................13 7.3.1. PDV ................................................13 7.3.2. IPDV ...............................................14 7.4. Frame Loss Rate ...........................................15 7.5. Back-to-Back Frames .......................................15 7.6. System Recovery ...........................................15 7.7. Reset .....................................................15 8. Additional Benchmarking Tests for Stateful IPv6 Transition Technologies ...................................................15 8.1. Concurrent TCP Connection Capacity ........................15 8.2. Maximum TCP Connection Establishment Rate .................15 9. DNS Resolution Performance .....................................15 9.1. Test and Traffic Setup ....................................16 9.2. Benchmarking DNS Resolution Performance ...................17 9.2.1. Requirements for the Tester ........................18 10. Overload Scalability ..........................................19 10.1. Test Setup ...............................................19 10.1.1. Single-Translation Transition Technologies ........19 10.1.2. Encapsulation and Double-Translation Transition Technologies ...........................20 10.2. Benchmarking Performance Degradation .....................21 10.2.1. Network Performance Degradation with Simultaneous Load .................................21 10.2.2. Network Performance Degradation with Incremental Load ..................................22 11. NAT44 and NAT66 ...............................................22 12. Summarizing Function and Variation ............................23 13. Security Considerations .......................................23 14. IANA Considerations ...........................................24 Georgescu, et al. Informational [Page 3] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 15. References ....................................................24 15.1. Normative References .....................................24 15.2. Informative References ...................................25 Appendix A. Theoretical Maximum Frame Rates........................29 Acknowledgements...................................................30 Authors' Addresses ................................................30 1. Introduction The methodologies described in [RFC2544] and [RFC5180] help vendors and network operators alike analyze the performance of IPv4 and IPv6-capable network devices. The methodology presented in [RFC2544] is mostly IP version independent, while [RFC5180] contains complementary recommendations that are specific to the latest IP version, IPv6. However, [RFC5180] does not cover IPv6 transition technologies. IPv6 is not backwards compatible, which means that IPv4-only nodes cannot directly communicate with IPv6-only nodes. To solve this issue, IPv6 transition technologies have been proposed and implemented. This document presents benchmarking guidelines dedicated to IPv6 transition technologies. The benchmarking tests can provide insights about the performance of these technologies, which can act as useful feedback for developers and network operators going through the IPv6 transition process. The document also includes an approach to quantify performance when operating in overload. Overload scalability can be defined as a system's ability to gracefully accommodate a greater number of flows than the maximum number of flows that the Device Under Test (DUT) can operate normally. The approach taken here is to quantify the overload scalability by measuring the performance created by an excessive number of network flows and comparing performance to the non-overloaded case. 1.1. IPv6 Transition Technologies Two of the basic transition technologies, dual IP layer (also known as dual stack) and encapsulation, are presented in [RFC4213]. IPv4/IPv6 translation is presented in [RFC6144]. Most of the transition technologies employ at least one variation of these mechanisms. In this context, a generic classification of the transition technologies can prove useful. Georgescu, et al. Informational [Page 4] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 We can consider a production network transitioning to IPv6 as being constructed using the following IP domains: o Domain A: IPvX-specific domain o Core domain: IPvY-specific or dual-stack (IPvX and IPvY) domain o Domain B: IPvX-specific domain Note: X,Y are part of the set {4,6}, and X is NOT EQUAL to Y. The transition technologies can be categorized according to the technology used for traversal of the core domain: 1. Dual stack: Devices in the core domain implement both IP protocols. 2. Single translation: In this case, the production network is assumed to have only two domains: Domain A and the core domain. The core domain is assumed to be IPvY specific. IPvX packets are translated to IPvY at the edge between Domain A and the core domain. 3. Double translation: The production network is assumed to have all three domains; Domains A and B are IPvX specific, while the core domain is IPvY specific. A translation mechanism is employed for the traversal of the core network. The IPvX packets are translated to IPvY packets at the edge between Domain A and the core domain. Subsequently, the IPvY packets are translated back to IPvX at the edge between the core domain and Domain B. 4. Encapsulation: The production network is assumed to have all three domains; Domains A and B are IPvX specific, while the core domain is IPvY specific. An encapsulation mechanism is used to traverse the core domain. The IPvX packets are encapsulated to IPvY packets at the edge between Domain A and the core domain. Subsequently, the IPvY packets are de-encapsulated at the edge between the core domain and Domain B. The performance of dual-stack transition technologies can be fully evaluated using the benchmarking methodologies presented by [RFC2544] and [RFC5180]. Consequently, this document focuses on the other three categories: single-translation, double-translation, and encapsulation transition technologies. Another important aspect by which IPv6 transition technologies can be categorized is their use of stateful or stateless mapping algorithms. The technologies that use stateful mapping algorithms (e.g., Stateful Georgescu, et al. Informational [Page 5] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 NAT64 [RFC6146]) create dynamic correlations between IP addresses or {IP address, transport protocol, transport port number} tuples, which are stored in a state table. For ease of reference, IPv6 transition technologies that employ stateful mapping algorithms will be called "stateful IPv6 transition technologies". The efficiency with which the state table is managed can be an important performance indicator for these technologies. Hence, additional benchmarking tests are RECOMMENDED for stateful IPv6 transition technologies. Table 1 contains the generic categories and associations with some of the IPv6 transition technologies proposed in the IETF. Please note that the list is not exhaustive. +---+--------------------+------------------------------------+ | | Generic category | IPv6 Transition Technology | +---+--------------------+------------------------------------+ | 1 | Dual stack | Dual IP Layer Operations [RFC4213] | +---+--------------------+------------------------------------+ | 2 | Single translation | NAT64 [RFC6146], IVI [RFC6219] | +---+--------------------+------------------------------------+ | 3 | Double translation | 464XLAT [RFC6877], MAP-T [RFC7599] | +---+--------------------+------------------------------------+ | 4 | Encapsulation | DS-Lite [RFC6333], MAP-E [RFC7597],| | | | Lightweight 4over6 [RFC7596], | | | | 6rd [RFC5569], 6PE [RFC4798], | | | | 6VPE [RFC4659] | +---+--------------------+------------------------------------+ Table 1: IPv6 Transition Technologies Categories 2. Conventions Used in This Document The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here. Although these terms are usually associated with protocol requirements, in this document, the terms are requirements for users and systems that intend to implement the test conditions and claim conformance with this specification. Georgescu, et al. Informational [Page 6] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 3. Terminology A number of terms used in this memo have been defined in other RFCs. Please refer to the RFCs below for definitions, testing procedures, and reporting formats. o Throughput (Benchmark) [RFC2544] o Frame Loss Rate (Benchmark) [RFC2544] o Back-to-Back Frames (Benchmark) [RFC2544] o System Recovery (Benchmark) [RFC2544] o Reset (Benchmark) [RFC6201] o Concurrent TCP Connection Capacity (Benchmark) [RFC3511] o Maximum TCP Connection Establishment Rate (Benchmark) [RFC3511] 4. Test Setup The test environment setup options recommended for benchmarking IPv6 transition technologies are very similar to the ones presented in Section 6 of [RFC2544]. In the case of the Tester setup, the options presented in [RFC2544] and [RFC5180] can be applied here as well. However, the DUT setup options should be explained in the context of the targeted categories of IPv6 transition technologies: single translation, double translation, and encapsulation. Although both single Tester and sender/receiver setups are applicable to this methodology, the single Tester setup will be used to describe the DUT setup options. For the test setups presented in this memo, dynamic routing SHOULD be employed. However, the presence of routing and management frames can represent unwanted background data that can affect the benchmarking result. To that end, the procedures defined in Sections 11.2 and 11.3 of [RFC2544] related to routing and management frames SHOULD be used here. Moreover, the "trial description" recommendations presented in Section 23 of [RFC2544] are also valid for this memo. In terms of route setup, the recommendations of Section 13 of [RFC2544] are valid for this document, assuming that IPv6-capable routing protocols are used. Georgescu, et al. Informational [Page 7] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 4.1. Single-Translation Transition Technologies For the evaluation of single-translation transition technologies, a single DUT setup (see Figure 1) SHOULD be used. The DUT is responsible for translating the IPvX packets into IPvY packets. In this context, the Tester device SHOULD be configured to support both IPvX and IPvY. +--------------------+ | | +------------|IPvX Tester IPvY|<-------------+ | | | | | +--------------------+ | | | | +--------------------+ | | | | | +----------->|IPvX DUT IPvY|--------------+ | | +--------------------+ Figure 1: Test Setup 1 (Single DUT) 4.2. Encapsulation and Double-Translation Transition Technologies For evaluating the performance of encapsulation and double- translation transition technologies, a dual DUT setup (see Figure 2) SHOULD be employed. The Tester creates a network flow of IPvX packets. The first DUT is responsible for the encapsulation or translation of IPvX packets into IPvY packets. The IPvY packets are de-encapsulated/translated back to IPvX packets by the second DUT and forwarded to the Tester. +--------------------+ | | +---------------------|IPvX Tester IPvX|<------------------+ | | | | | +--------------------+ | | | | +--------------------+ +--------------------+ | | | | | | | +----->|IPvX DUT 1 IPvY |----->|IPvY DUT 2 IPvX |------+ | | | | +--------------------+ +--------------------+ Figure 2: Test Setup 2 (Dual DUT) Georgescu, et al. Informational [Page 8] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 One of the limitations of the dual DUT setup is the inability to reflect asymmetries in behavior between the DUTs. Considering this, additional performance tests SHOULD be performed using the single DUT setup. Note: For encapsulation IPv6 transition technologies in the single DUT setup, the Tester SHOULD be able to send IPvX packets encapsulated as IPvY in order to test the de-encapsulation efficiency. 5. Test Traffic The test traffic represents the experimental workload and SHOULD meet the requirements specified in this section. The requirements are dedicated to unicast IP traffic. Multicast IP traffic is outside of the scope of this document. 5.1. Frame Formats and Sizes [RFC5180] describes the frame size requirements for two commonly used media types: Ethernet and SONET (Synchronous Optical Network). [RFC2544] also covers other media types, such as token ring and Fiber Distributed Data Interface (FDDI). The recommendations of those two documents can be used for the dual-stack transition technologies. For the rest of the transition technologies, the frame overhead introduced by translation or encapsulation MUST be considered. The encapsulation/translation process generates different size frames on different segments of the test setup. For instance, the single- translation transition technologies will create different frame sizes on the receiving segment of the test setup, as IPvX packets are translated to IPvY. This is not a problem if the bandwidth of the employed media is not exceeded. To prevent exceeding the limitations imposed by the media, the frame size overhead needs to be taken into account when calculating the maximum theoretical frame rates. The calculation method for the Ethernet, as well as a calculation example, are detailed in Appendix A. The details of the media employed for the benchmarking tests MUST be noted in all test reports. In the context of frame size overhead, MTU recommendations are needed in order to avoid frame loss due to MTU mismatch between the virtual encapsulation/translation interfaces and the physical network interface controllers (NICs). To avoid this situation, the larger MTU between the physical NICs and virtual encapsulation/translation interfaces SHOULD be set for all interfaces of the DUT and Tester. Georgescu, et al. Informational [Page 9] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 To be more specific, the minimum IPv6 MTU size (1280 bytes) plus the encapsulation/translation overhead is the RECOMMENDED value for the physical interfaces as well as virtual ones. 5.1.1. Frame Sizes to Be Used over Ethernet Based on the recommendations of [RFC5180], the following frame sizes SHOULD be used for benchmarking IPvX/IPvY traffic on Ethernet links: 64, 128, 256, 512, 768, 1024, 1280, 1518, 1522, 2048, 4096, 8192, and 9216. For Ethernet frames exceeding 1500 bytes in size, the [IEEE802.1AC] standard can be consulted. Note: For single-translation transition technologies (e.g., NAT64) in the IPv6 -> IPv4 translation direction, 64-byte frames SHOULD be replaced by 84-byte frames. This would allow the frames to be transported over media such as the ones described by the [IEEE802.1Q] standard. Moreover, this would also allow the implementation of a frame identifier in the UDP data. The theoretical maximum frame rates considering an example of frame overhead are presented in Appendix A. 5.2. Protocol Addresses The selected protocol addresses should follow the recommendations of Section 5 of [RFC5180] for IPv6 and Section 12 of [RFC2544] for IPv4. Note: Testing traffic with extension headers might not be possible for the transition technologies that employ translation. Proposed IPvX/IPvY translation algorithms such as IP/ICMP translation [RFC7915] do not support the use of extension headers. 5.3. Traffic Setup Following the recommendations of [RFC5180], all tests described SHOULD be performed with bidirectional traffic. Unidirectional traffic tests MAY also be performed for a fine-grained performance assessment. Because of the simplicity of UDP, UDP measurements offer a more reliable basis for comparison than other transport-layer protocols. Consequently, for the benchmarking tests described in Section 7 of this document, UDP traffic SHOULD be employed. Georgescu, et al. Informational [Page 10] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 Considering that a transition technology could process both native IPv6 traffic and translated/encapsulated traffic, the following traffic setups are recommended: i) IPvX only traffic (where the IPvX traffic is to be translated/encapsulated by the DUT) ii) 90% IPvX traffic and 10% IPvY native traffic iii) 50% IPvX traffic and 50% IPvY native traffic iv) 10% IPvX traffic and 90% IPvY native traffic For the benchmarks dedicated to stateful IPv6 transition technologies, included in Section 8 of this memo (Concurrent TCP Connection Capacity and Maximum TCP Connection Establishment Rate), the traffic SHOULD follow the recommendations of Sections 5.2.2.2 and 5.3.2.2 of [RFC3511]. 6. Modifiers The idea of testing under different operational conditions was first introduced in Section 11 of [RFC2544] and represents an important aspect of benchmarking network elements, as it emulates, to some extent, the conditions of a production environment. Section 6 of [RFC5180] describes complementary test conditions specific to IPv6. The recommendations in [RFC2544] and [RFC5180] can also be followed for testing of IPv6 transition technologies. 7. Benchmarking Tests The following sub-sections describe all recommended benchmarking tests. 7.1. Throughput Use Section 26.1 of [RFC2544] unmodified. 7.2. Latency Objective: To determine the latency. Typical latency is based on the definitions of latency from [RFC1242]. However, this memo provides a new measurement procedure. Procedure: Similar to [RFC2544], the throughput for DUT at each of the listed frame sizes SHOULD be determined. Send a stream of frames at a particular frame size through the DUT at the determined throughput rate to a specific destination. The stream SHOULD be at least 120 seconds in duration. Georgescu, et al. Informational [Page 11] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 Identifying tags SHOULD be included in at least 500 frames after 60 seconds. For each tagged frame, the time at which the frame was fully transmitted (timestamp A) and the time at which the frame was received (timestamp B) MUST be recorded. The latency is timestamp B minus timestamp A as per the relevant definition from RFC 1242, namely, latency as defined for store and forward devices or latency as defined for bit forwarding devices. We recommend encoding the identifying tag in the payload of the frame. To be more exact, the identifier SHOULD be inserted after the UDP header. From the resulted (at least 500) latencies, two quantities SHOULD be calculated. One is the typical latency, which SHOULD be calculated with the following formula: TL = Median(Li) Where: o TL = the reported typical latency of the stream o Li = the latency for tagged frame i The other measure is the worst-case latency, which SHOULD be calculated with the following formula: WCL = L99.9thPercentile Where: o WCL = the reported worst-case latency o L99.9thPercentile = the 99.9th percentile of the stream-measured latencies The test MUST be repeated at least 20 times with the reported value being the median of the recorded values for TL and WCL. Reporting Format: The report MUST state which definition of latency (from RFC 1242) was used for this test. The summarized latency results SHOULD be reported in the format of a table with a row for each of the tested frame sizes. There SHOULD be columns for the frame size, the rate at which the latency test was run for that frame size, the media types tested, and the resultant typical latency, and the worst-case latency values for each type of data stream tested. To account for the variation, the 1st and 99th percentiles of the 20 Georgescu, et al. Informational [Page 12] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 iterations MAY be reported in two separated columns. For a fine- grained analysis, the histogram (as exemplified in Section 4.4 of [RFC5481]) of one of the iterations MAY be displayed. 7.3. Packet Delay Variation [RFC5481] presents two metrics: Packet Delay Variation (PDV) and Inter Packet Delay Variation (IPDV). Measuring PDV is RECOMMENDED; for a fine-grained analysis of delay variation, IPDV measurements MAY be performed. 7.3.1. PDV Objective: To determine the Packet Delay Variation as defined in [RFC5481]. Procedure: As described by [RFC2544], first determine the throughput for the DUT at each of the listed frame sizes. Send a stream of frames at a particular frame size through the DUT at the determined throughput rate to a specific destination. The stream SHOULD be at least 60 seconds in duration. Measure the one-way delay as described by [RFC3393] for all frames in the stream. Calculate the PDV of the stream using the formula: PDV = D99.9thPercentile - Dmin Where: o D99.9thPercentile = the 99.9th percentile (as described in [RFC5481]) of the one-way delay for the stream o Dmin = the minimum one-way delay in the stream As recommended in [RFC2544], the test MUST be repeated at least 20 times with the reported value being the median of the recorded values. Moreover, the 1st and 99th percentiles SHOULD be calculated to account for the variation of the dataset. Reporting Format: The PDV results SHOULD be reported in a table with a row for each of the tested frame sizes and columns for the frame size and the applied frame rate for the tested media types. Two columns for the 1st and 99th percentile values MAY be displayed. Following the recommendations of [RFC5481], the RECOMMENDED units of measurement are milliseconds. Georgescu, et al. Informational [Page 13] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 7.3.2. IPDV Objective: To determine the Inter Packet Delay Variation as defined in [RFC5481]. Procedure: As described by [RFC2544], first determine the throughput for the DUT at each of the listed frame sizes. Send a stream of frames at a particular frame size through the DUT at the determined throughput rate to a specific destination. The stream SHOULD be at least 60 seconds in duration. Measure the one-way delay as described by [RFC3393] for all frames in the stream. Calculate the IPDV for each of the frames using the formula: IPDV(i) = D(i) - D(i-1) Where: o D(i) = the one-way delay of the i-th frame in the stream o D(i-1) = the one-way delay of (i-1)th frame in the stream Given the nature of IPDV, reporting a single number might lead to over-summarization. In this context, the report for each measurement SHOULD include three values: Dmin, Dmed, and Dmax. Where: o Dmin = the minimum IPDV in the stream o Dmed = the median IPDV of the stream o Dmax = the maximum IPDV in the stream The test MUST be repeated at least 20 times. To summarize the 20 repetitions, for each of the three (Dmin, Dmed, and Dmax), the median value SHOULD be reported. Reporting format: The median for the three proposed values SHOULD be reported. The IPDV results SHOULD be reported in a table with a row for each of the tested frame sizes. The columns SHOULD include the frame size and associated frame rate for the tested media types and sub-columns for the three proposed reported values. Following the recommendations of [RFC5481], the RECOMMENDED units of measurement are milliseconds. Georgescu, et al. Informational [Page 14] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 7.4. Frame Loss Rate Use Section 26.3 of [RFC2544] unmodified. 7.5. Back-to-Back Frames Use Section 26.4 of [RFC2544] unmodified. 7.6. System Recovery Use Section 26.5 of [RFC2544] unmodified. 7.7. Reset Use Section 4 of [RFC6201] unmodified. 8. Additional Benchmarking Tests for Stateful IPv6 Transition Technologies This section describes additional tests dedicated to stateful IPv6 transition technologies. For the tests described in this section, the DUT devices SHOULD follow the test setup and test parameters recommendations presented in Sections 5.2 and 5.3 of [RFC3511]. The following additional tests SHOULD be performed. 8.1. Concurrent TCP Connection Capacity Use Section 5.2 of [RFC3511] unmodified. 8.2. Maximum TCP Connection Establishment Rate Use Section 5.3 of [RFC3511] unmodified. 9. DNS Resolution Performance This section describes benchmarking tests dedicated to DNS64 (see [RFC6147]), used as DNS support for single-translation technologies such as NAT64. Georgescu, et al. Informational [Page 15] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 9.1. Test and Traffic Setup The test setup in Figure 3 follows the setup proposed for single- translation IPv6 transition technologies in Figure 1. 1:AAAA query +--------------------+ +------------| |<-------------+ | |IPv6 Tester IPv4| | | +-------->| |----------+ | | | +--------------------+ 3:empty | | | | 6:synt'd AAAA, | | | | AAAA +--------------------+ 5:valid A| | | +---------| |<---------+ | | |IPv6 DUT IPv4| | +----------->| (DNS64) |--------------+ +--------------------+ 2:AAAA query, 4:A query Figure 3: Test Setup 3 (DNS64) The test traffic SHOULD be composed of the following messages. 1. Query for the AAAA record of a domain name (from client to DNS64 server) 2. Query for the AAAA record of the same domain name (from DNS64 server to authoritative DNS server) 3. Empty AAAA record answer (from authoritative DNS server to DNS64 server) 4. Query for the A record of the same domain name (from DNS64 server to authoritative DNS server) 5. Valid A record answer (from authoritative DNS server to DNS64 server) 6. Synthesized AAAA record answer (from DNS64 server to client) The Tester plays the role of DNS client as well as authoritative DNS server. It MAY be realized as a single physical device, or alternatively, two physical devices MAY be used. Please note that: o If the DNS64 server implements caching and there is a cache hit, then step 1 is followed by step 6 (and steps 2 through 5 are omitted). Georgescu, et al. Informational [Page 16] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 o If the domain name has a AAAA record, then it is returned in step 3 by the authoritative DNS server, steps 4 and 5 are omitted, and the DNS64 server does not synthesize a AAAA record but returns the received AAAA record to the client. o As for the IP version used between the Tester and the DUT, IPv6 MUST be used between the client and the DNS64 server (as a DNS64 server provides service for an IPv6-only client), but either IPv4 or IPv6 MAY be used between the DNS64 server and the authoritative DNS server. 9.2. Benchmarking DNS Resolution Performance Objective: To determine DNS64 performance by means of the maximum number of successfully processed DNS requests per second. Procedure: Send a specific number of DNS queries at a specific rate to the DUT, and then count the replies from the DUT that are received in time (within a predefined timeout period from the sending time of the corresponding query, having the default value 1 second) and that are valid (contain a AAAA record). If the count of sent queries is equal to the count of received replies, the rate of the queries is raised, and the test is rerun. If fewer replies are received than queries were sent, the rate of the queries is reduced, and the test is rerun. The duration of each trial SHOULD be at least 60 seconds. This will reduce the potential gain of a DNS64 server, which is able to exhibit higher performance by storing the requests and thus also utilizing the timeout time for answering them. For the same reason, no higher timeout time than 1 second SHOULD be used. For further considerations, see [Lencse1]. The maximum number of processed DNS queries per second is the fastest rate at which the count of DNS replies sent by the DUT is equal to the number of DNS queries sent to it by the test equipment. The test SHOULD be repeated at least 20 times, and the median and 1st/99th percentiles of the number of processed DNS queries per second SHOULD be calculated. Details and parameters: 1. Caching First, all the DNS queries MUST contain different domain names (or domain names MUST NOT be repeated before the cache of the DUT is exhausted). Then, new tests MAY be executed when domain names are 20%, 40%, 60%, 80%, and 100% cached. Ensuring that a record Georgescu, et al. Informational [Page 17] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 is cached requires repeating a domain name both "late enough" after the first query to be already resolved and be present in the cache and "early enough" to be still present in the cache. 2. Existence of a AAAA record First, all the DNS queries MUST contain domain names that do not have a AAAA record and have exactly one A record. Then, new tests MAY be executed when 20%, 40%, 60%, 80%, and 100% of domain names have a AAAA record. Please note that the two conditions above are orthogonal; thus, all their combinations are possible and MAY be tested. The testing with 0% cached domain names and with 0% existing AAAA records is REQUIRED, and the other combinations are OPTIONAL. (When all the domain names are cached, then the results do not depend on what percentage of the domain names have AAAA records; thus, these combinations are not worth testing one by one.) Reporting format: The primary result of the DNS64 test is the median of the number of processed DNS queries per second measured with the above mentioned "0% + 0% combination". The median SHOULD be complemented with the 1st and 99th percentiles to show the stability of the result. If optional tests are done, the median and the 1st and 99th percentiles MAY be presented in a two-dimensional table where the dimensions are the proportion of the repeated domain names and the proportion of the DNS names having AAAA records. The two table headings SHOULD contain these percentage values. Alternatively, the results MAY be presented as a corresponding two- dimensional graph. In this case, the graph SHOULD show the median values with the percentiles as error bars. From both the table and the graph, one-dimensional excerpts MAY be made at any given fixed- percentage value of the other dimension. In this case, the fixed value MUST be given together with a one-dimensional table or graph. 9.2.1. Requirements for the Tester Before a Tester can be used for testing a DUT at rate r queries per second with t seconds timeout, it MUST perform a self-test in order to exclude the possibility that the poor performance of the Tester itself influences the results. To perform a self-test, the Tester is looped back (leaving out DUT), and its authoritative DNS server subsystem is configured to be able to answer all the AAAA record queries. To pass the self-test, the Tester SHOULD be able to answer AAAA record queries at rate of 2*(r+delta) within a 0.25*t timeout, where the value of delta is at least 0.1. Georgescu, et al. Informational [Page 18] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 Explanation: When performing DNS64 testing, each AAAA record query may result in at most two queries sent by the DUT: the first for a AAAA record and the second for an A record (they are both sent when there is no cache hit and also no AAAA record exists). The parameters above guarantee that the authoritative DNS server subsystem of the DUT is able to answer the queries at the required frequency using up not more than half of the timeout time. Note: A sample open-source test program, dns64perf++, is available from [Dns64perf] and is documented in [Lencse2]. It implements only the client part of the Tester and should be used together with an authoritative DNS server implementation, e.g., BIND, NSD, or YADIFA. Its experimental extension for testing caching is available from [Lencse3] and is documented in [Lencse4]. 10. Overload Scalability Scalability has been often discussed; however, in the context of network devices, a formal definition or a measurement method has not yet been proposed. In this context, we can define overload scalability as the ability of each transition technology to accommodate network growth. Poor scalability usually leads to poor performance. Considering this, overload scalability can be measured by quantifying the network performance degradation associated with an increased number of network flows. The following subsections describe how the test setups can be modified to create network growth and how the associated performance degradation can be quantified. 10.1. Test Setup The test setups defined in Section 4 have to be modified to create network growth. 10.1.1. Single-Translation Transition Technologies In the case of single-translation transition technologies, the network growth can be generated by increasing the number of network flows (NFs) generated by the Tester machine (see Figure 4). Georgescu, et al. Informational [Page 19] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 +-------------------------+ +------------|NF1 NF1|<-------------+ | +---------|NF2 Tester NF2|<----------+ | | | ...| | | | | | +-----|NFn NFn|<------+ | | | | | +-------------------------+ | | | | | | | | | | | | +-------------------------+ | | | | | +---->|NFn NFn|-------+ | | | | ...| DUT | | | | +-------->|NF2 (translator) NF2|-----------+ | +----------->|NF1 NF1|--------------+ +-------------------------+ Figure 4: Test Setup 4 (Single DUT with Increased Network Flows) 10.1.2. Encapsulation and Double-Translation Transition Technologies Similarly, for the encapsulation and double-translation transition technologies, a multi-flow setup is recommended. Considering a multipoint-to-point scenario, for most transition technologies, one of the edge nodes is designed to support more than one connecting device. Hence, the recommended test setup is an n:1 design, where n is the number of client DUTs connected to the same server DUT (see Figure 5). +-------------------------+ +--------------------|NF1 NF1|<--------------+ | +-----------------|NF2 Tester NF2|<-----------+ | | | ...| | | | | | +-------------|NFn NFn|<-------+ | | | | | +-------------------------+ | | | | | | | | | | | | +-----------------+ +---------------+ | | | | | +--->| NFn DUT n NFn |--->|NFn NFn| ---+ | | | | +-----------------+ | | | | | | ... | | | | | | +-----------------+ | DUT n+1 | | | | +------->| NF2 DUT 2 NF2 |--->|NF2 NF2|--------+ | | +-----------------+ | | | | +-----------------+ | | | +---------->| NF1 DUT 1 NF1 |--->|NF1 NF1|-----------+ +-----------------+ +---------------+ Figure 5: Test Setup 5 (DUAL DUT with Increased Network Flows) Georgescu, et al. Informational [Page 20] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 This test setup can help to quantify the scalability of the server device. However, for testing the overload scalability of the client DUTs, additional recommendations are needed. For encapsulation transition technologies, an m:n setup can be created, where m is the number of flows applied to the same client device and n the number of client devices connected to the same server device. For translation-based transition technologies, the client devices can be separately tested with n network flows using the test setup presented in Figure 4. 10.2. Benchmarking Performance Degradation 10.2.1. Network Performance Degradation with Simultaneous Load Objective: To quantify the performance degradation introduced by n parallel and simultaneous network flows. Procedure: First, the benchmarking tests presented in Section 7 have to be performed for one network flow. The same tests have to be repeated for n network flows, where the network flows are started simultaneously. The performance degradation of the X benchmarking dimension SHOULD be calculated as relative performance change between the 1-flow (single flow) results and the n-flow results, using the following formula: Xn - X1 Xpd = ----------- * 100, where: X1 = result for 1-flow X1 Xn = result for n-flows This formula SHOULD be applied only for "lower is better" benchmarks (e.g., latency). For "higher is better" benchmarks (e.g., throughput), the following formula is RECOMMENDED: X1 - Xn Xpd = ----------- * 100, where: X1 = result for 1-flow X1 Xn = result for n-flows As a guideline for the maximum number of flows n, the value can be deduced by measuring the Concurrent TCP Connection Capacity as described by [RFC3511], following the test setups specified by Section 4. Georgescu, et al. Informational [Page 21] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 Reporting Format: The performance degradation SHOULD be expressed as a percentage. The number of tested parallel flows n MUST be clearly specified. For each of the performed benchmarking tests, there SHOULD be a table containing a column for each frame size. The table SHOULD also state the applied frame rate. In the case of benchmarks for which more than one value is reported (e.g., IPDV, discussed in Section 7.3.2), a column for each of the values SHOULD be included. 10.2.2. Network Performance Degradation with Incremental Load Objective: To quantify the performance degradation introduced by n parallel and incrementally started network flows. Procedure: First, the benchmarking tests presented in Section 7 have to be performed for one network flow. The same tests have to be repeated for n network flows, where the network flows are started incrementally in succession, each after time t. In other words, if flow i is started at time x, flow i+1 will be started at time x+t. Considering the time t, the time duration of each iteration must be extended with the time necessary to start all the flows, namely, (n-1)xt. The measurement for the first flow SHOULD be at least 60 seconds in duration. The performance degradation of the x benchmarking dimension SHOULD be calculated as relative performance change between the 1-flow results and the n-flow results, using the formula presented in Section 10.2.1. Intermediary degradation points for 1/4*n, 1/2*n, and 3/4*n MAY also be performed. Reporting Format: The performance degradation SHOULD be expressed as a percentage. The number of tested parallel flows n MUST be clearly specified. For each of the performed benchmarking tests, there SHOULD be a table containing a column for each frame size. The table SHOULD also state the applied frame rate and time duration T, which is used as an incremental step between the network flows. The units of measurement for T SHOULD be seconds. A column for the intermediary degradation points MAY also be displayed. In the case of benchmarks for which more than one value is reported (e.g., IPDV, discussed in Section 7.3.2), a column for each of the values SHOULD be included. 11. NAT44 and NAT66 Although these technologies are not the primary scope of this document, the benchmarking methodology associated with single- translation technologies as defined in Section 4.1 can be employed to Georgescu, et al. Informational [Page 22] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 benchmark implementations that use NAT44 (as defined by [RFC2663] with the behavior described by [RFC7857]) and implementations that use NAT66 (as defined by [RFC6296]). 12. Summarizing Function and Variation To ensure the stability of the benchmarking scores obtained using the tests presented in Sections 7 through 9, multiple test iterations are RECOMMENDED. Using a summarizing function (or measure of central tendency) can be a simple and effective way to compare the results obtained across different iterations. However, over-summarization is an unwanted effect of reporting a single number. Measuring the variation (dispersion index) can be used to counter the over-summarization effect. Empirical data obtained following the proposed methodology can also offer insights on which summarizing function would fit better. To that end, data presented in [ietf95pres] indicate the median as a suitable summarizing function and the 1st and 99th percentiles as variation measures for DNS Resolution Performance and PDV. The median and percentile calculation functions SHOULD follow the recommendations of Section 11.3 of [RFC2330]. For a fine-grained analysis of the frequency distribution of the data, histograms or cumulative distribution function plots can be employed. 13. 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. Further, benchmarking is performed on a "black-box" basis, relying solely on measurements observable external to the DUT or System Under Test (SUT). 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. Georgescu, et al. Informational [Page 23] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 14. IANA Considerations The IANA has allocated the prefix 2001:2::/48 [RFC5180] for IPv6 benchmarking. For IPv4 benchmarking, the 198.18.0.0/15 prefix was reserved, as described in [RFC6890]. The two ranges are sufficient for benchmarking IPv6 transition technologies. Thus, no action is requested. 15. References 15.1. Normative References [RFC1242] Bradner, S., "Benchmarking Terminology for Network Interconnection Devices", RFC 1242, DOI 10.17487/RFC1242, July 1991, <http://www.rfc-editor.org/info/rfc1242>. [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997, <http://www.rfc-editor.org/info/rfc2119>. [RFC2330] Paxson, V., Almes, G., Mahdavi, J., and M. Mathis, "Framework for IP Performance Metrics", RFC 2330, DOI 10.17487/RFC2330, May 1998, <http://www.rfc-editor.org/info/rfc2330>. [RFC2544] Bradner, S. and J. McQuaid, "Benchmarking Methodology for Network Interconnect Devices", RFC 2544, DOI 10.17487/RFC2544, March 1999, <http://www.rfc-editor.org/info/rfc2544>. [RFC3393] Demichelis, C. and P. Chimento, "IP Packet Delay Variation Metric for IP Performance Metrics (IPPM)", RFC 3393, DOI 10.17487/RFC3393, November 2002, <http://www.rfc-editor.org/info/rfc3393>. [RFC3511] Hickman, B., Newman, D., Tadjudin, S., and T. Martin, "Benchmarking Methodology for Firewall Performance", RFC 3511, DOI 10.17487/RFC3511, April 2003, <http://www.rfc-editor.org/info/rfc3511>. [RFC5180] Popoviciu, C., Hamza, A., Van de Velde, G., and D. Dugatkin, "IPv6 Benchmarking Methodology for Network Interconnect Devices", RFC 5180, DOI 10.17487/RFC5180, May 2008, <http://www.rfc-editor.org/info/rfc5180>. Georgescu, et al. Informational [Page 24] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 [RFC5481] Morton, A. and B. Claise, "Packet Delay Variation Applicability Statement", RFC 5481, DOI 10.17487/RFC5481, March 2009, <http://www.rfc-editor.org/info/rfc5481>. [RFC6201] Asati, R., Pignataro, C., Calabria, F., and C. Olvera, "Device Reset Characterization", RFC 6201, DOI 10.17487/RFC6201, March 2011, <http://www.rfc-editor.org/info/rfc6201>. [RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, May 2017, <http://www.rfc-editor.org/info/rfc8174>. 15.2. Informative References [RFC2663] Srisuresh, P. and M. Holdrege, "IP Network Address Translator (NAT) Terminology and Considerations", RFC 2663, DOI 10.17487/RFC2663, August 1999, <http://www.rfc-editor.org/info/rfc2663>. [RFC4213] Nordmark, E. and R. Gilligan, "Basic Transition Mechanisms for IPv6 Hosts and Routers", RFC 4213, DOI 10.17487/RFC4213, October 2005, <http://www.rfc-editor.org/info/rfc4213>. [RFC4659] De Clercq, J., Ooms, D., Carugi, M., and F. Le Faucheur, "BGP-MPLS IP Virtual Private Network (VPN) Extension for IPv6 VPN", RFC 4659, DOI 10.17487/RFC4659, September 2006, <http://www.rfc-editor.org/info/rfc4659>. [RFC4798] De Clercq, J., Ooms, D., Prevost, S., and F. Le Faucheur, "Connecting IPv6 Islands over IPv4 MPLS Using IPv6 Provider Edge Routers (6PE)", RFC 4798, DOI 10.17487/RFC4798, February 2007, <http://www.rfc-editor.org/info/rfc4798>. [RFC5569] Despres, R., "IPv6 Rapid Deployment on IPv4 Infrastructures (6rd)", RFC 5569, DOI 10.17487/RFC5569, January 2010, <http://www.rfc-editor.org/info/rfc5569>. [RFC6144] Baker, F., Li, X., Bao, C., and K. Yin, "Framework for IPv4/IPv6 Translation", RFC 6144, DOI 10.17487/RFC6144, April 2011, <http://www.rfc-editor.org/info/rfc6144>. [RFC6146] Bagnulo, M., Matthews, P., and I. van Beijnum, "Stateful NAT64: Network Address and Protocol Translation from IPv6 Clients to IPv4 Servers", RFC 6146, DOI 10.17487/RFC6146, April 2011, <http://www.rfc-editor.org/info/rfc6146>. Georgescu, et al. Informational [Page 25] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 [RFC6147] Bagnulo, M., Sullivan, A., Matthews, P., and I. van Beijnum, "DNS64: DNS Extensions for Network Address Translation from IPv6 Clients to IPv4 Servers", RFC 6147, DOI 10.17487/RFC6147, April 2011, <http://www.rfc-editor.org/info/rfc6147>. [RFC6219] Li, X., Bao, C., Chen, M., Zhang, H., and J. Wu, "The China Education and Research Network (CERNET) IVI Translation Design and Deployment for the IPv4/IPv6 Coexistence and Transition", RFC 6219, DOI 10.17487/RFC6219, May 2011, <http://www.rfc-editor.org/info/rfc6219>. [RFC6296] Wasserman, M. and F. Baker, "IPv6-to-IPv6 Network Prefix Translation", RFC 6296, DOI 10.17487/RFC6296, June 2011, <http://www.rfc-editor.org/info/rfc6296>. [RFC6333] Durand, A., Droms, R., Woodyatt, J., and Y. Lee, "Dual- Stack Lite Broadband Deployments Following IPv4 Exhaustion", RFC 6333, DOI 10.17487/RFC6333, August 2011, <http://www.rfc-editor.org/info/rfc6333>. [RFC6877] Mawatari, M., Kawashima, M., and C. Byrne, "464XLAT: Combination of Stateful and Stateless Translation", RFC 6877, DOI 10.17487/RFC6877, April 2013, <http://www.rfc-editor.org/info/rfc6877>. [RFC6890] Cotton, M., Vegoda, L., Bonica, R., Ed., and B. Haberman, "Special-Purpose IP Address Registries", BCP 153, RFC 6890, DOI 10.17487/RFC6890, April 2013, <http://www.rfc-editor.org/info/rfc6890>. [RFC7596] Cui, Y., Sun, Q., Boucadair, M., Tsou, T., Lee, Y., and I. Farrer, "Lightweight 4over6: An Extension to the Dual- Stack Lite Architecture", RFC 7596, DOI 10.17487/RFC7596, July 2015, <http://www.rfc-editor.org/info/rfc7596>. [RFC7597] Troan, O., Ed., Dec, W., Li, X., Bao, C., Matsushima, S., Murakami, T., and T. Taylor, Ed., "Mapping of Address and Port with Encapsulation (MAP-E)", RFC 7597, DOI 10.17487/RFC7597, July 2015, <http://www.rfc-editor.org/info/rfc7597>. [RFC7599] Li, X., Bao, C., Dec, W., Ed., Troan, O., Matsushima, S., and T. Murakami, "Mapping of Address and Port using Translation (MAP-T)", RFC 7599, DOI 10.17487/RFC7599, July 2015, <http://www.rfc-editor.org/info/rfc7599>. Georgescu, et al. Informational [Page 26] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 [RFC7857] Penno, R., Perreault, S., Boucadair, M., Ed., Sivakumar, S., and K. Naito, "Updates to Network Address Translation (NAT) Behavioral Requirements", BCP 127, RFC 7857, DOI 10.17487/RFC7857, April 2016, <http://www.rfc-editor.org/info/rfc7857>. [RFC7915] Bao, C., Li, X., Baker, F., Anderson, T., and F. Gont, "IP/ICMP Translation Algorithm", RFC 7915, DOI 10.17487/RFC7915, June 2016, <http://www.rfc-editor.org/info/rfc7915>. [Dns64perf] Bakai, D., "A C++11 DNS64 performance tester", <https://github.com/bakaid/dns64perfpp>. [ietf95pres] Georgescu, M., "Benchmarking Methodology for IPv6 Transition Technologies", IETF 95 Proceedings, Buenos Aires, Argentina, April 2016, <https://www.ietf.org/proceedings/95/slides/ slides-95-bmwg-2.pdf>. [Lencse1] Lencse, G., Georgescu, M., and Y. Kadobayashi, "Benchmarking Methodology for DNS64 Servers", Computer Communications, vol. 109, no. 1, pp. 162-175, DOI 10.1016/j.comcom.2017.06.004, September 2017, <http://www.sciencedirect.com/science/article/pii/ S0140366416305904?via%3Dihub> [Lencse2] Lencse, G. and D. Bakai, "Design and Implementation of a Test Program for Benchmarking DNS64 Servers", IEICE Transactions on Communications, Vol. E100-B, No. 6, pp. 948-954, DOI 10.1587/transcom.2016EBN0007, June 2017, <https://www.jstage.jst.go.jp/article/transcom/E100.B/ 6/E100.B_2016EBN0007/_article>. [Lencse3] dns64perfppc, <http://www.hit.bme.hu/~lencse/dns64perfppc/>. [Lencse4] Lencse, G., "Enabling Dns64perf++ for Benchmarking the Caching Performance of DNS64 Servers", unpublished, review version, <http://www.hit.bme.hu/~lencse/publications/ IEICE-2016-dns64perfppc-for-review.pdf>. Georgescu, et al. Informational [Page 27] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 [IEEE802.1AC] IEEE, "IEEE Standard for Local and metropolitan area networks -- Media Access Control (MAC) Service Definition", IEEE 802.1AC. [IEEE802.1Q] IEEE, "IEEE Standard for Local and metropolitan area networks -- Bridges and Bridged Networks", IEEE Std 802.1Q. Georgescu, et al. Informational [Page 28] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 Appendix A. Theoretical Maximum Frame Rates This appendix describes the recommended calculation formulas for the theoretical maximum frame rates to be employed over Ethernet as example media. The formula takes into account the frame size overhead created by the encapsulation or translation process. For example, the 6in4 encapsulation described in [RFC4213] adds 20 bytes of overhead to each frame. Considering X to be the frame size and O to be the frame size overhead created by the encapsulation or translation process, the maximum theoretical frame rate for Ethernet can be calculated using the following formula: Line Rate (bps) ------------------------------------ (8 bits/byte) * (X+O+20) bytes/frame The calculation is based on the formula recommended by [RFC5180] in Appendix A.1. As an example, the frame rate recommended for testing a 6in4 implementation over 10 Mb/s Ethernet with 64 bytes frames is: 10,000,000 (bps) -------------------------------------- = 12,019 fps (8 bits/byte) * (64+20+20) bytes/frame The complete list of recommended frame rates for 6in4 encapsulation can be found in the following table: +------------+---------+----------+-----------+------------+ | Frame size | 10 Mb/s | 100 Mb/s | 1000 Mb/s | 10000 Mb/s | | (bytes) | (fps) | (fps) | (fps) | (fps) | +------------+---------+----------+-----------+------------+ | 64 | 12,019 | 120,192 | 1,201,923 | 12,019,231 | | 128 | 7,440 | 74,405 | 744,048 | 7,440,476 | | 256 | 4,223 | 42,230 | 422,297 | 4,222,973 | | 512 | 2,264 | 22,645 | 226,449 | 2,264,493 | | 678 | 1,740 | 17,409 | 174,094 | 1,740,947 | | 1024 | 1,175 | 11,748 | 117,481 | 1,174,812 | | 1280 | 947 | 9,470 | 94,697 | 946,970 | | 1518 | 802 | 8,023 | 80,231 | 802,311 | | 1522 | 800 | 8,003 | 80,026 | 800,256 | | 2048 | 599 | 5,987 | 59,866 | 598,659 | | 4096 | 302 | 3,022 | 30,222 | 302,224 | | 8192 | 152 | 1,518 | 15,185 | 151,846 | | 9216 | 135 | 1,350 | 13,505 | 135,048 | +------------+---------+----------+-----------+------------+ Georgescu, et al. Informational [Page 29] RFC 8219 Benchmarking for IPv6 Transition Technologies August 2017 Acknowledgements The authors thank Youki Kadobayashi and Hiroaki Hazeyama for their constant feedback and support. The thanks should be extended to the NECOMA project members for their continuous support. We thank Emanuel Popa, Ionut Spirlea, and the RCS&RDS IP/MPLS Backbone Team for their support and insights. We thank Scott Bradner for the useful suggestions and note that portions of text from Scott's documents were used in this memo (e.g., the "Latency" section). A big thank you to Al Morton and Fred Baker for their detailed review of the document and very helpful suggestions. Other helpful comments and suggestions were offered by Bhuvaneswaran Vengainathan, Andrew McGregor, Nalini Elkins, Kaname Nishizuka, Yasuhiro Ohara, Masataka Mawatari, Kostas Pentikousis, Bela Almasi, Tim Chown, Paul Emmerich, and Stenio Fernandes. A special thank you to the RFC Editor Team for their thorough editorial review and helpful suggestions. Authors' Addresses Marius Georgescu RCS&RDS Strada Dr. Nicolae D. Staicovici 71-75 Bucharest 030167 Romania Phone: +40 31 005 0979 Email: marius.georgescu@rcs-rds.ro Liviu Pislaru RCS&RDS Strada Dr. Nicolae D. Staicovici 71-75 Bucharest 030167 Romania Phone: +40 31 005 0979 Email: liviu.pislaru@rcs-rds.ro Gabor Lencse Szechenyi Istvan University Egyetem ter 1. Gyor Hungary Phone: +36 20 775 8267 Email: lencse@sze.hu Georgescu, et al. Informational [Page 30]