GENWiki



Internet Engineering Task Force (IETF) B. Balarajah Request for Comments: 9411 Obsoletes: 3511 C. Rossenhoevel Category: Informational EANTC AG ISSN: 2070-1721 B. Monkman

                                                            NetSecOPEN
                                                            March 2023

  Benchmarking Methodology for Network Security Device Performance

Abstract

 This document provides benchmarking terminology and methodology for
 next-generation network security devices, including next-generation
 firewalls (NGFWs) and next-generation intrusion prevention systems
 (NGIPSs).  The main areas covered in this document are test
 terminology, test configuration parameters, and benchmarking
 methodology for NGFWs and NGIPSs.  (It is assumed that readers have a
 working knowledge of these devices and the security functionality
 they contain.)  This document aims to improve the applicability,
 reproducibility, and transparency of benchmarks and to align the test
 methodology with today's increasingly complex layer 7 security-
 centric network application use cases.  As a result, this document
 makes RFC 3511 obsolete.

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 candidates 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
 https://www.rfc-editor.org/info/rfc9411.

Copyright Notice

 Copyright (c) 2023 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
 (https://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 Revised BSD License text as described in Section 4.e of the
 Trust Legal Provisions and are provided without warranty as described
 in the Revised BSD License.

Table of Contents

 1.  Introduction
 2.  Requirements Language
 3.  Scope
 4.  Test Setup
   4.1.  Testbed Configuration
   4.2.  DUT/SUT Configuration
     4.2.1.  Security Effectiveness Configuration
   4.3.  Test Equipment Configuration
     4.3.1.  Client Configuration
     4.3.2.  Backend Server Configuration
     4.3.3.  Traffic Flow Definition
     4.3.4.  Traffic Load Profile
 5.  Testbed Considerations
 6.  Reporting
   6.1.  Introduction
   6.2.  Detailed Test Results
   6.3.  Benchmarks and Key Performance Indicators
 7.  Benchmarking Tests
   7.1.  Throughput Performance with Application Traffic Mix
     7.1.1.  Objective
     7.1.2.  Test Setup
     7.1.3.  Test Parameters
     7.1.4.  Test Procedures and Expected Results
   7.2.  TCP Connections Per Second with HTTP Traffic
     7.2.1.  Objective
     7.2.2.  Test Setup
     7.2.3.  Test Parameters
     7.2.4.  Test Procedures and Expected Results
   7.3.  HTTP Throughput
     7.3.1.  Objective
     7.3.2.  Test Setup
     7.3.3.  Test Parameters
     7.3.4.  Test Procedures and Expected Results
   7.4.  HTTP Transaction Latency
     7.4.1.  Objective
     7.4.2.  Test Setup
     7.4.3.  Test Parameters
     7.4.4.  Test Procedures and Expected Results
   7.5.  Concurrent TCP Connection Capacity with HTTP Traffic
     7.5.1.  Objective
     7.5.2.  Test Setup
     7.5.3.  Test Parameters
     7.5.4.  Test Procedures and Expected Results
   7.6.  TCP or QUIC Connections per Second with HTTPS Traffic
     7.6.1.  Objective
     7.6.2.  Test Setup
     7.6.3.  Test Parameters
     7.6.4.  Test Procedures and Expected Results
   7.7.  HTTPS Throughput
     7.7.1.  Objective
     7.7.2.  Test Setup
     7.7.3.  Test Parameters
     7.7.4.  Test Procedures and Expected Results
   7.8.  HTTPS Transaction Latency
     7.8.1.  Objective
     7.8.2.  Test Setup
     7.8.3.  Test Parameters
     7.8.4.  Test Procedures and Expected Results
   7.9.  Concurrent TCP or QUIC Connection Capacity with HTTPS
         Traffic
     7.9.1.  Objective
     7.9.2.  Test Setup
     7.9.3.  Test Parameters
     7.9.4.  Test Procedures and Expected Results
 8.  IANA Considerations
 9.  Security Considerations
 10. References
   10.1.  Normative References
   10.2.  Informative References
 Appendix A.  Test Methodology - Security Effectiveness Evaluation
   A.1.  Test Objective
   A.2.  Testbed Setup
   A.3.  Test Parameters
     A.3.1.  DUT/SUT Configuration Parameters
     A.3.2.  Test Equipment Configuration Parameters
   A.4.  Test Results Validation Criteria
   A.5.  Measurement
   A.6.  Test Procedures and Expected Results
     A.6.1.  Step 1: Background Traffic
     A.6.2.  Step 2: CVE Emulation
 Appendix B.  DUT/SUT Classification
 Acknowledgements
 Contributors
 Authors' Addresses

1. Introduction

 It has been 18 years since the IETF initially recommended test
 methodology and terminology for firewalls [RFC3511].  Firewalls have
 evolved significantly from the days of simple access control list
 (ACL) filters.  As the underlying technology progresses and improves,
 recommending test methodology and terminology for firewalls,
 requirements, and expectations for network security elements has
 increased tremendously.  Security function implementations have
 evolved and diversified into intrusion detection and prevention,
 threat management, analysis of encrypted traffic, and more.  In an
 industry of growing importance, well-defined and reproducible key
 performance indicators (KPIs) are increasingly needed to enable fair
 and reasonable comparisons of network security functions.  These
 reasons led to the creation of a new next-generation network security
 device benchmarking document, which makes [RFC3511] obsolete.  The
 measurement of performance for processing IP-fragmented traffic (see
 Section 5.9 of [RFC3511])is not included in this document since IP
 fragmentation does not commonly occur in traffic anymore, unlike how
 it might have at the time when [RFC3511] was written.  It should also
 be noted that [RFC2647] retains significant value and was consulted
 frequently while creating this document.

 For a more detailed explanation of what an NGFW is, see the Wikipedia
 article [Wiki-NGFW].

2. Requirements Language

 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.

3. Scope

 This document provides testing terminology and testing methodology
 for modern and next-generation network security devices that are
 configured in Active ("Inline", see Figures 1 and 2) mode.  It covers
 the validation of security effectiveness configurations of network
 security devices, followed by performance benchmark testing.  This
 document focuses on advanced, realistic, and reproducible testing
 methods.  Additionally, it describes testbed environments, test tool
 requirements, and test result formats.

 The performance testing methodology described in this document is not
 intended for security devices or systems that rely on machine
 learning or behavioral analysis.  If such features are present in a
 Device Under Test / System Under Test (DUT/SUT), they should be
 disabled.

4. Test Setup

 The test setup defined in this document applies to all benchmarking
 tests described in Section 7.  The test setup MUST be contained
 within an isolated test environment (see Section 3 of [RFC6815]).

4.1. Testbed Configuration

 Testbed configuration MUST ensure that any performance implications
 that are discovered during the benchmark testing aren't due to the
 inherent physical network limitations, such as the number of physical
 links and forwarding performance capabilities (throughput and
 latency) of the network devices in the testbed.  For this reason,
 this document recommends avoiding external devices, such as switches
 and routers, in the testbed wherever possible.

 In some deployment scenarios, the network security devices (DUT/SUT)
 are connected to routers and switches, which will reduce the number
 of entries in MAC (Media Access Control) or Address Resolution
 Protocol / Neighbor Discovery (ARP/ND) tables of the DUT/SUT.  If MAC
 or ARP/ND tables have many entries, this may impact the actual DUT/
 SUT performance due to MAC and ARP/ND table lookup processes.  This
 document also recommends using test equipment with the capability of
 emulating layer 3 routing functionality instead of adding external
 routers in the testbed.

 The testbed setup for Option 1 (Figure 1) is the RECOMMENDED testbed
 setup for the benchmarking test.

 +-----------------------+                   +-----------------------+
 | +-------------------+ |   +-----------+   | +-------------------+ |
 | | Emulated Router(s)| |   |           |   | | Emulated Router(s)| |
 | |    (Optional)     | +----- DUT/SUT  +-----+    (Optional)     | |
 | +-------------------+ |   |           |   | +-------------------+ |
 | +-------------------+ |   +-----------+   | +-------------------+ |
 | |     Clients       | |                   | |      Servers      | |
 | +-------------------+ |                   | +-------------------+ |
 |                       |                   |                       |
 |   Test Equipment      |                   |   Test Equipment      |
 +-----------------------+                   +-----------------------+

                   Figure 1: Testbed Setup - Option 1

 If the test equipment used is not capable of emulating OSI layer 3
 routing functionality or if the number of used ports is mismatched
 between the test equipment and the DUT/SUT (which is needed for test
 equipment port aggregation), the test setup can be configured as
 shown in Figure 2.

  +-------------------+      +-----------+      +--------------------+
  |Aggregation Switch/|      |           |      | Aggregation Switch/|
  | Router            +------+  DUT/SUT  +------+ Router             |
  |                   |      |           |      |                    |
  +----------+--------+      +-----------+      +--------+-----------+
             |                                           |
             |                                           |
 +-----------+-----------+                   +-----------+-----------+
 |                       |                   |                       |
 | +-------------------+ |                   | +-------------------+ |
 | | Emulated Router(s)| |                   | | Emulated Router(s)| |
 | |     (Optional)    | |                   | |     (Optional)    | |
 | +-------------------+ |                   | +-------------------+ |
 | +-------------------+ |                   | +-------------------+ |
 | |      Clients      | |                   | |      Servers      | |
 | +-------------------+ |                   | +-------------------+ |
 |                       |                   |                       |
 |    Test Equipment     |                   |    Test Equipment     |
 +-----------------------+                   +-----------------------+

                   Figure 2: Testbed Setup - Option 2

4.2. DUT/SUT Configuration

 The same DUT/SUT configuration MUST be used for all benchmarking
 tests described in Section 7.  Since each DUT/SUT will have its own
 unique configuration, users MUST configure their devices with the
 same parameters and security features that would be used in the
 actual deployment of the device or a typical deployment.  The DUT/SUT
 MUST be configured in "Inline" mode so that the traffic is actively
 inspected by the DUT/SUT.

 Tables 2 and 3 below describe the RECOMMENDED and OPTIONAL sets of
 network security features for NGFWs and NGIPSs, respectively.  If the
 recommended security features are not enabled in the DUT/SUT for any
 reason, the reason MUST be reported with the benchmarking test
 results.  For example, one reason for not enabling the anti-virus
 feature in an NGFW may be that this security feature was not required
 for a particular customer deployment scenario.  It MUST be also noted
 in the benchmarking test report that not enabling the specific
 recommended security features may impact the performance of the DUT/
 SUT.  The selected security features MUST be consistently enabled on
 the DUT/SUT for all benchmarking tests described in Section 7.

 To improve repeatability, a summary of the DUT/SUT configuration,
 including a description of all enabled DUT/SUT features, MUST be
 published with the benchmarking results.

 The following table provides a brief description of the security
 feature; these are approximate taxonomies of features commonly found
 in currently deployed NGFWs and NGIPSs.  The features provided by
 specific implementations may be named differently and not necessarily
 have configuration settings that align with the taxonomy.

 +================+==================================================+
 | DUT/SUT        | Description                                      |
 | Features       |                                                  |
 +================+==================================================+
 | TLS Inspection | The DUT/SUT intercepts and decrypts              |
 |                | inbound HTTPS traffic between servers and        |
 |                | clients.  Once the content inspection has        |
 |                | been completed, the DUT/SUT encrypts the         |
 |                | HTTPS traffic with ciphers and keys used         |
 |                | by the clients and servers.  For TLS 1.3,        |
 |                | the DUT works as a middlebox (proxy) and         |
 |                | holds the certificates and Pre-Shared Keys       |
 |                | (PSKs) that are trusted by the client and        |
 |                | represent the identity of the real server.       |
 +----------------+--------------------------------------------------+
 | IDS/IPS        | The DUT/SUT detects and blocks exploits          |
 |                | targeting known and unknown                      |
 |                | vulnerabilities across the monitored             |
 |                | network.                                         |
 +----------------+--------------------------------------------------+
 | Anti-Malware   | The DUT/SUT detects and prevents the             |
 |                | transmission of malicious executable code        |
 |                | and any associated communications across         |
 |                | the monitored network.  This includes data       |
 |                | exfiltration as well as command and              |
 |                | control channels.                                |
 +----------------+--------------------------------------------------+
 | Anti-Spyware   | Anti-Spyware is a subcategory of Anti-           |
 |                | Malware.  Spyware transmits information          |
 |                | without the user's knowledge or                  |
 |                | permission.  The DUT/SUT detects and             |
 |                | blocks the initial infection or                  |
 |                | transmission of data.                            |
 +----------------+--------------------------------------------------+
 | Anti-Botnet    | The DUT/SUT detects and blocks traffic to        |
 |                | or from botnets.                                 |
 +----------------+--------------------------------------------------+
 | Anti-Evasion   | The DUT/SUT detects and mitigates attacks        |
 |                | that have been obfuscated in some manner.        |
 +----------------+--------------------------------------------------+
 | Web Filtering  | The DUT/SUT detects and blocks malicious         |
 |                | websites, including defined                      |
 |                | classifications of websites across the           |
 |                | monitored network.                               |
 +----------------+--------------------------------------------------+
 | Data Loss      | The DUT/SUT detects and prevents data            |
 | Protection     | breaches and data exfiltration, or it            |
 | (DLP)          | detects and blocks the transmission of           |
 |                | sensitive data across the monitored              |
 |                | network.                                         |
 +----------------+--------------------------------------------------+
 | Certificate    | The DUT/SUT validates certificates used in       |
 | Validation     | encrypted communications across the              |
 |                | monitored network.                               |
 +----------------+--------------------------------------------------+
 | Logging and    | The DUT/SUT logs and reports all traffic         |
 | Reporting      | at the flow level across the monitored           |
 |                | network.                                         |
 +----------------+--------------------------------------------------+
 | Application    | The DUT/SUT detects known applications as        |
 | Identification | defined within the traffic mix selected          |
 |                | across the monitored network.                    |
 +----------------+--------------------------------------------------+
 | Deep Packet    | The DUT/SUT inspects the content of the          |
 | Inspection     | data packet.                                     |
 | (DPI)          |                                                  |
 +----------------+--------------------------------------------------+

                 Table 1: Security Feature Description

        +============================+=============+==========+
        | DUT/SUT (NGFW) Features    | RECOMMENDED | OPTIONAL |
        +============================+=============+==========+
        | TLS Inspection             |      x      |          |
        +----------------------------+-------------+----------+
        | IDS/IPS                    |      x      |          |
        +----------------------------+-------------+----------+
        | Anti-Spyware               |      x      |          |
        +----------------------------+-------------+----------+
        | Anti-Virus                 |      x      |          |
        +----------------------------+-------------+----------+
        | Anti-Botnet                |      x      |          |
        +----------------------------+-------------+----------+
        | Anti-Evasion               |      x      |          |
        +----------------------------+-------------+----------+
        | Web Filtering              |             |    x     |
        +----------------------------+-------------+----------+
        | Data Loss Protection (DLP) |             |    x     |
        +----------------------------+-------------+----------+
        | DDoS Protection            |             |    x     |
        +----------------------------+-------------+----------+
        | Certificate Validation     |             |    x     |
        +----------------------------+-------------+----------+
        | Application Identification |      x      |          |
        +----------------------------+-------------+----------+

                    Table 2: NGFW Security Features

       +==============================+=============+==========+
       | DUT/SUT (NGIPS) Features     | RECOMMENDED | OPTIONAL |
       +==============================+=============+==========+
       | TLS Inspection               |      x      |          |
       +------------------------------+-------------+----------+
       | Anti-Malware                 |      x      |          |
       +------------------------------+-------------+----------+
       | Anti-Spyware                 |      x      |          |
       +------------------------------+-------------+----------+
       | Anti-Botnet                  |      x      |          |
       +------------------------------+-------------+----------+
       | Application Identification   |      x      |          |
       +------------------------------+-------------+----------+
       | Deep Packet Inspection (DPI) |      x      |          |
       +------------------------------+-------------+----------+
       | Anti-Evasion                 |      x      |          |
       +------------------------------+-------------+----------+

                    Table 3: NGIPS Security Features

 Note: With respect to TLS Inspection, there are scenarios where it
 will be optional.

 Below is a summary of the DUT/SUT configuration:

• The DUT/SUT MUST be configured in "Inline" mode.

• "Fail-Open" behavior MUST be disabled.

• All RECOMMENDED security features are enabled.

• Logging and reporting MUST be enabled. The DUT/SUT SHOULD log all

traffic at the flow level (5-tuple). If the DUT/SUT is designed

    to log all traffic at different levels (e.g., IP packet levels),
    it is acceptable to conduct tests.  However, this MUST be noted in
    the test report.  Logging to an external device is permissible.

• Geographical location filtering SHOULD be configured. If the DUT/

SUT is not designed to perform geographical location filtering, it

    is acceptable to conduct tests without this feature.  However,
    this MUST be noted in the test report.

• Application Identification and Control MUST be configured to

trigger applications from the defined traffic mix.

 In addition, a realistic number of access control lists (ACLs) SHOULD
 be configured on the DUT/SUT where ACLs are configurable and
 reasonable based on the deployment scenario.  For example, it is
 acceptable not to configure ACLs in an NGIPS since NGIPS devices do
 not require the use of ACLs in most deployment scenarios.  This
 document determines the number of access policy rules for four
 different classes of the DUT/SUT: Extra Small (XS), Small (S), Medium
 (M), and Large (L).  A sample DUT/SUT classification is described in
 Appendix B.

 The ACLs defined in Table 4 MUST be configured from top to bottom in
 the correct order, as shown in the table.  This is due to ACL types
 listed in specificity-decreasing order, with "block" first, followed
 by "allow", representing a typical ACL-based security policy.  The
 ACL entries MUST be configured with routable IP prefixes by the DUT/
 SUT, where applicable.  (Note: There will be differences between how
 security vendors implement ACL decision making.)  The configured ACL
 MUST NOT block the test traffic used for the benchmarking tests.

 +===================================================+==============+
 |                                                   |DUT/SUT       |
 |                                                   |Classification|
 |                                                   |# Rules       |
 +=============+=============+==============+========+===+==+===+===+
 | Rules Type  | Match       | Description  | Action |XS |S |M  |L  |
 |             | Criteria    |              |        |   |  |   |   |
 +=============+=============+==============+========+===+==+===+===+
 | Application | Application | Any          | block  |5  |10|20 |50 |
 | layer       |             | application  |        |   |  |   |   |
 |             |             | not included |        |   |  |   |   |
 |             |             | in the       |        |   |  |   |   |
 |             |             | measurement  |        |   |  |   |   |
 |             |             | traffic      |        |   |  |   |   |
 +-------------+-------------+--------------+--------+---+--+---+---+
 | Transport   | SRC IP and  | Any SRC IP   | block  |25 |50|100|250|
 | layer       | TCP/UDP DST | prefix used  |        |   |  |   |   |
 |             | ports       | and any DST  |        |   |  |   |   |
 |             |             | ports not    |        |   |  |   |   |
 |             |             | used in the  |        |   |  |   |   |
 |             |             | measurement  |        |   |  |   |   |
 |             |             | traffic      |        |   |  |   |   |
 +-------------+-------------+--------------+--------+---+--+---+---+
 | IP layer    | SRC/DST IP  | Any SRC/DST  | block  |25 |50|100|250|
 |             |             | IP subnet    |        |   |  |   |   |
 |             |             | not used in  |        |   |  |   |   |
 |             |             | the          |        |   |  |   |   |
 |             |             | measurement  |        |   |  |   |   |
 |             |             | traffic      |        |   |  |   |   |
 +-------------+-------------+--------------+--------+---+--+---+---+
 | Application | Application | Half of the  | allow  |10 |10|10 |10 |
 | layer       |             | applications |        |   |  |   |   |
 |             |             | included in  |        |   |  |   |   |
 |             |             | the          |        |   |  |   |   |
 |             |             | measurement  |        |   |  |   |   |
 |             |             | traffic (see |        |   |  |   |   |
 |             |             | the note     |        |   |  |   |   |
 |             |             | below)       |        |   |  |   |   |
 +-------------+-------------+--------------+--------+---+--+---+---+
 | Transport   | SRC IP and  | Half of the  | allow  |>1 |>1|>1 |>1 |
 | layer       | TCP/UDP DST | SRC IPs used |        |   |  |   |   |
 |             | ports       | and any DST  |        |   |  |   |   |
 |             |             | ports used   |        |   |  |   |   |
 |             |             | in the       |        |   |  |   |   |
 |             |             | measurement  |        |   |  |   |   |
 |             |             | traffic (one |        |   |  |   |   |
 |             |             | rule per     |        |   |  |   |   |
 |             |             | subnet)      |        |   |  |   |   |
 +-------------+-------------+--------------+--------+---+--+---+---+
 | IP layer    | SRC IP      | The rest of  | allow  |>1 |>1|>1 |>1 |
 |             |             | the SRC IP   |        |   |  |   |   |
 |             |             | prefix range |        |   |  |   |   |
 |             |             | used in the  |        |   |  |   |   |
 |             |             | measurement  |        |   |  |   |   |
 |             |             | traffic (one |        |   |  |   |   |
 |             |             | rule per     |        |   |  |   |   |
 |             |             | subnet)      |        |   |  |   |   |
 +-------------+-------------+--------------+--------+---+--+---+---+

                     Table 4: DUT/SUT Access List

 Note 1: Based on the test customer's specific use case, the testers
 can increase the number of rules.

 Note 2: If half of the applications included in the test traffic are
 less than 10, the missing number of ACL entries (placeholder rules)
 can be configured for any application traffic not included in the
 test traffic.

 Note 3: In the event that the DUT/SUT is designed to not use ACLs, it
 is acceptable to conduct tests without them.  However, this MUST be
 noted in the test report.

4.2.1. Security Effectiveness Configuration

 The selected security features (defined in Tables 2 and 3) of the
 DUT/SUT MUST be configured effectively to detect, prevent, and report
 the defined security vulnerability sets.  This section defines the
 selection of the security vulnerability sets from the Common
 Vulnerabilities and Exposures (CVEs) list [CVE] for testing.  The
 vulnerability set should reflect a minimum of 500 CVEs from no older
 than 10 calendar years to the current year.  These CVEs should be
 selected with a focus on in-use software commonly found in business
 applications, with a Common Vulnerability Scoring System (CVSS)
 Severity of High (7-10).

 This document is primarily focused on performance benchmarking.
 However, it is RECOMMENDED to validate the security features
 configuration of the DUT/SUT by evaluating the security effectiveness
 as a prerequisite for performance benchmarking tests defined in
 Section 7.  In case the benchmarking tests are performed without
 evaluating security effectiveness, the test report MUST explain the
 implications of this.  The methodology for evaluating security
 effectiveness is defined in Appendix A.

4.3. Test Equipment Configuration

 In general, test equipment allows configuring parameters in different
 protocol layers.  Extensive proof-of-concept tests conducted to
 support preparation of this document showed that benchmarking results
 are strongly affected by the choice of protocol stack parameters,
 especially OSI layer 4 transport protocol parameters.  For more
 information on how TCP and QUIC parameters will impact performance,
 review [fastly].  To achieve reproducible results that will be
 representative of real deployment scenarios, careful specification
 and documentation of the parameters are required.

 This section specifies common test equipment configuration parameters
 applicable for all benchmarking tests defined in Section 7.  Any
 benchmarking-test-specific parameters are described under the test
 setup section of each benchmarking test individually.

4.3.1. Client Configuration

 This section specifies which parameters should be considered while
 configuring emulated client endpoints in the test equipment.  Also,
 this section specifies the RECOMMENDED values for certain parameters.
 The values are the defaults typically used in most of the client
 operating system types.

 Pre-standard evaluations have shown that it is possible to set a wide
 range of arbitrary parameters for OSI layer 4 transport protocols on
 test equipment leading to optimization of client-specific results;
 however, only well-defined common parameter sets help to establish
 meaningful and comparable benchmarking results.  For these reasons,
 this document recommends specific sets of transport protocol
 parameters to be configured on test equipment used for benchmarking.

4.3.1.1. TCP Stack Attributes

 The TCP stack of the emulated client endpoints MUST fulfill the TCP
 requirements defined in Appendix B of [RFC9293].  In addition, this
 section specifies the RECOMMENDED values for TCP parameters
 configured using the parameters described below.

 The IPv4 and IPv6 Maximum Segment Sizes (MSSs) are set to 1460 bytes
 and 1440 bytes, respectively.  TX and RX initial receive window sizes
 are set to 65535 bytes.  The client's initial congestion window
 should not exceed 10 times the MSS.  Delayed ACKs are permitted, and
 the maximum client delayed ACK should not exceed 10 times of the MSS
 before a forced ACK; also, the maximum delayed ACK timer is allowed
 to be set to 200 ms.  Up to three retries are allowed before a
 timeout event is declared.  The TCP PSH flag is set to high in all
 traffic.  The source port range is 1024-65535.  The clients initiate
 TCP connections via a three-way handshake (SYN, SYN/ACK, ACK) and
 close TCP connections via either a TCP three-way close (FIN, FIN/ACK,
 ACK) or a TCP four-way close (FIN, ACK, FIN, ACK).

4.3.1.2. QUIC Specification

 QUIC stack emulation on the test equipment MUST conform to [RFC9000]
 and [RFC9001].  This section specifies the RECOMMENDED values for
 certain QUIC parameters to be configured on test equipment used for
 benchmarking purposes only.  The QUIC stream type (defined in
 Section 2.1 of [RFC9000]) is set to "Client-Initiated,
 Bidirectional". 0-RTT and early data are disabled.  The QUIC
 connection termination method is an immediate close (Section 10.2 of
 [RFC9000]).  Flow control is enabled.  UDP payloads are set to the
 datagram size of 1232 bytes for IPv6 and 1252 bytes for IPv4.  In
 addition, transport parameters and default values defined in
 Section 18.2 of [RFC9000] are RECOMMENDED to configure on test
 equipment.  Also, this document references Appendices B.1 and B.2 of
 [RFC9002] for congestion-control-related constants and variables.
 Any configured QUIC and UDP parameter MUST be documented in the test
 report.

4.3.1.3. Client IP Address Space

 The client IP space contains the following attributes.

• If multiple IP blocks are used, they MUST consist of multiple

unique, discontinuous static address blocks.

• A default gateway MAY be used.

• The differentiated services code point (DSCP) marking should be

set to Default Forwarding (DF) '000000' on the IPv4 Type of

    Service (ToS) field and IPv6 Traffic Class field.

• One or more extension headers MAY be used for IPv6 clients. If

multiple extension headers are needed for traffic emulation, this

    document references [RFC8200] to choose the correct order of the
    extension headers within an IPv6 packet.  Testing with one or more
    extension headers may impact the performance of the DUT.  The
    extension headers MUST be documented and reported.

 The following equation can be used to define the total number of
 client IP addresses that need to be configured on the test equipment.

    Desired total number of client IP addresses = Target throughput
    [Mbit/s] / Average throughput per IP address [Mbit/s]

 As shown in the example list below, the value for "Average throughput
 per IP address" can be varied depending on the deployment and use
 case scenario.

 Example 1  DUT/SUT deployment scenario 1: 6-7 Mbit/s per IP (e.g.,
            1,400-1,700 IPs per 10 Gbit/s of throughput)

 Example 2  DUT/SUT deployment scenario 2: 0.1-0.2 Mbit/s per IP
            (e.g., 50,000-100,000 IPs per 10 Gbit/s of throughput)

 Client IP addresses MUST be distributed between IPv4 and IPv6 based
 on the deployment and use case scenario.  The following options MAY
 be considered for a selection of ratios for both IP addresses and
 traffic load distribution.

 Option 1  100 % IPv4, no IPv6

 Option 2  80 % IPv4, 20% IPv6

 Option 3  50 % IPv4, 50% IPv6

 Option 4  20 % IPv4, 80% IPv6

 Option 5  no IPv4, 100% IPv6

 Note: IANA has assigned IP address ranges for testing purposes, as
 described in Section 8.  If the test scenario requires more IP
 addresses or subnets than IANA has assigned, this document recommends
 using private IPv4 address ranges or Unique Local Address (ULA) IPv6
 address ranges for the testing.

4.3.1.4. Emulated Web Browser Attributes

 The client (emulated web browser) contains attributes that will
 materially affect the traffic load.  The objective is to emulate
 modern, typical browser attributes to improve the relevance of the
 result set for typical deployment scenarios.

 The emulated browser MUST negotiate HTTP version 1.1 or higher.  The
 emulated browser SHOULD advertise a User-Agent header.  The emulated
 browser MUST enforce content length validation.  HTTP header
 compression MAY be set to enable.  If HTTP header compression is
 configurable in the test equipment, it MUST be documented if it was
 enabled or disabled.  Depending on test scenarios and the chosen HTTP
 version, the emulated browser MAY open multiple TCP or QUIC
 connections per server endpoint IP at any time, depending on how many
 sequential transactions need to be processed.

 For HTTP/2 traffic emulation, the emulated browser opens multiple
 concurrent streams per connection (multiplexing).  For HTTPS
 requests, the emulated browser MUST send an "h2" protocol identifier
 using the TLS extension Application-Layer Protocol Negotiation
 (ALPN).  The following default values (see [Undertow]) are the
 RECOMMENDED settings for certain HTTP/2 parameters to be configured
 on test equipment used for benchmarking purposes only:

• Maximum frame size: 16384 bytes

• Initial window size: 65535 bytes

• HPACK header field table size: 4096 bytes

• Server push enable: false (Note: In [Undertow], the default

setting is true. However, for testing purposes, this document

    recommends setting the value to false for server push.)

 This document refers to [RFC9113] for further details of HTTP/2.  If
 any additional parameters are used to configure the test equipment,
 they MUST be documented.

 For HTTP/3 traffic emulation, the emulated browsers initiate secure
 QUIC connections using TLS 1.3 ([RFC9001] describes how TLS is used
 to secure QUIC).  This document refers to [RFC9114] for HTTP/3
 specifications.  The specification for transport protocol parameters
 is defined in Section 4.3.1.2.  QPACK configuration settings, such as
 MAX_TABLE_CAPACITY and QPACK_BLOCKED_STREAMS, are set to zero
 (default), as defined in [RFC9204].  Any HTTP/3 parameters used for
 test equipment configuration MUST be documented.

 For encrypted traffic, the following attributes are defined as the
 negotiated encryption parameters.  The test clients MUST use TLS
 version 1.2 or higher.  The TLS record size MAY be optimized for the
 HTTPS response object size, up to a record size of 16 KB.  If Server
 Name Indication (SNI) is required (especially if the server is
 identified by a domain name), the client endpoint MUST send TLS
 extension SNI information when opening a security tunnel.  Each
 client connection MUST perform a full TLS handshake, and session
 reuse or resumption MUST be disabled.  (Note: Real web browsers use
 session reuse or resumption.  However, for testing purposes, this
 feature must not be used to measure the DUT/SUT performance in the
 worst-case scenario.)

 The following ciphers and keys supported by TLS 1.2 are RECOMMENDED
 for the HTTPS-based benchmarking tests defined in Section 7.

 1.  ECDHE-ECDSA-AES128-GCM-SHA256 with Prime256v1 (Signature Hash
     Algorithm: ecdsa_secp256r1_sha256 and Supported group: secp256r1)

 2.  ECDHE-RSA-AES128-GCM-SHA256 with RSA 2048 (Signature Hash
     Algorithm: rsa_pkcs1_sha256 and Supported group: secp256r1)

 3.  ECDHE-ECDSA-AES256-GCM-SHA384 with Secp384r1 (Signature Hash
     Algorithm: ecdsa_secp384r1_sha384 and Supported group: secp384r1)

 4.  ECDHE-RSA-AES256-GCM-SHA384 with RSA 4096 (Signature Hash
     Algorithm: rsa_pkcs1_sha384 and Supported group: secp384r1)

 Note: The above ciphers and keys were those commonly used for
 enterprise-grade encryption cipher suites for TLS 1.2 at of the time
 of publication (2023).  Individual certification bodies should use
 ciphers and keys that reflect evolving use cases.  These choices MUST
 be documented in the resulting test reports with detailed information
 on the ciphers and keys used, along with reasons for the choices.

 IANA recommends the following cipher suites for use with TLS 1.3, as
 defined in [RFC8446].

 1.  TLS_AES_128_GCM_SHA256

 2.  TLS_AES_256_GCM_SHA384

 3.  TLS_CHACHA20_POLY1305_SHA256

 4.  TLS_AES_128_CCM_SHA256

4.3.2. Backend Server Configuration

 This section specifies which parameters should be considered while
 configuring emulated backend servers using test equipment.

4.3.2.1. TCP Stack Attributes

 The TCP stack on the server-side MUST be configured similarly to the
 client-side configuration described in Section 4.3.1.1.

4.3.2.2. QUIC Specification

 The QUIC parameters on the server-side MUST be configured similarly
 to the client-side configuration.  Any configured QUIC parameter MUST
 be documented in the report.

4.3.2.3. Server Endpoint IP Addressing

 The sum of the server IP space MUST contain the following attributes.

• The server IP blocks MUST consist of unique, discontinuous static

address blocks with one IP per server Fully Qualified Domain Name

    (FQDN) endpoint per test port.

• A default gateway is permitted. The DSCP marking is set to DF

'000000' on the IPv4 ToS field and IPv6 Traffic Class field. One

    or more extension headers for the IPv6 server are permitted.  If
    multiple extension headers are required, this document references
    [RFC8200] to choose the correct order of the extension headers
    within an IPv6 packet.

• The server IP address distribution between IPv4 and IPv6 MUST be

identical to the client IP address distribution ratio.

 Note: IANA has assigned IP address blocks for the testing purpose
 described in Section 8.  If the test scenario requires more IP
 addresses or address blocks than IANA has assigned, this document
 recommends using private IPv4 address ranges or Unique Local Address
 (ULA) IPv6 address ranges for the testing.

4.3.2.4. HTTP/HTTPS Server Pool Endpoint Attributes

 The HTTP 1.1 and HTTP/2 server pools listen on TCP ports 80 and 443
 for HTTP and HTTPS.  The HTTP/3 server pool listens on any UDP port.
 The server MUST emulate the same HTTP version (HTTP 1.1, HTTP/2, or
 HTTP/3) and settings chosen by the client (emulated web browser).
 For the HTTPS server, TLS version 1.2 or higher MUST be used with a
 maximum record size of 16 KB.  Ticket resumption or session ID reuse
 MUST NOT be used for TLS 1.2; also, session ticket or session cache
 MUST NOT be used for TLS 1.3.  The server MUST serve a certificate to
 the client.  The cipher suite and key size on the server-side MUST be
 configured similarly to the client-side configuration described in
 Section 4.3.1.4.

4.3.3. Traffic Flow Definition

 At the beginning of the test (the init phase; see Section 4.3.4), the
 server endpoint initializes, and the server endpoint will be ready to
 accept TCP or QUIC connections as well as inbound HTTP and HTTPS
 requests.  The client endpoints initialize and are given attributes
 such as a MAC and IP address.  After the init phase of the test, each
 client sweeps through the given server IP space, generating a service
 recognizable by the DUT.  Sequential and pseudorandom sweep methods
 are acceptable.  The method used MUST be stated in the final report.
 Thus, a balanced mesh between client endpoints and server endpoints
 will be generated in a client IP and port to server IP and port
 combination.  Each client endpoint performs the same actions as other
 endpoints, with the difference being the source IP of the client
 endpoint and the target server IP pool.  The client MUST use the
 server IP address or FQDN in the host header.

4.3.3.1. Description of Intra-Client Behavior

 Client endpoints are independent of other clients that are
 concurrently executing.  When a client endpoint initiates traffic,
 this section describes how the client steps through different
 services.  Once the test is initialized, the client endpoints
 randomly hold (perform no operation) for a few milliseconds for
 better randomization of the start of client traffic.  Each client
 (HTTP 1.1 or HTTP/2) will either open a new TCP connection or connect
 to an HTTP persistent connection that is still open to that specific
 server.  HTTP/3 clients will open UDP streams within QUIC
 connections.  At any point that the traffic profile may require
 encryption, a TLS encryption tunnel will form, presenting the URL or
 IP address request to the server.  If using SNI, the server MUST then
 perform an SNI name check by comparing the proposed FQDN to the
 domain embedded in the certificate.  Only when correct will the
 server process the HTTPS response object.  The initial response
 object to the server is based on benchmarking tests described in
 Section 7.  Multiple additional sub-URLs (response objects on the
 service page) MAY be requested simultaneously.  This MAY be to the
 same server IP as the initial URL.  Each sub-object will also use a
 canonical FQDN and URL path.

4.3.4. Traffic Load Profile

 The loading of traffic is described in this section.  The loading of
 a traffic load profile has five phases: Init, ramp up, sustain, ramp
 down, and collection.

 Init phase:
    Testbed devices, including the client and server endpoints, should
    negotiate layer 2-3 connectivity, such as MAC learning and ARP/ND.
    Only after successful MAC learning or ARP/ND SHALL the test
    iteration move to the next phase.  No measurements are made in
    this phase.  The minimum recommended time for the Init phase is 5
    seconds.  During this phase, the emulated clients MUST NOT
    initiate any sessions with the DUT/SUT; in contrast, the emulated
    servers should be ready to accept requests from the DUT/SUT or
    emulated clients.

 Ramp Up phase:
    The test equipment MUST start to generate the test traffic.  It
    MUST use a set of the approximate number of unique client IP
    addresses to generate traffic.  The traffic MUST ramp up from zero
    to the desired target objective.  The target objective is defined
    for each benchmarking test.  The duration for the ramp up phase
    MUST be configured long enough that the test equipment does not
    overwhelm the DUT's/SUT's stated performance metrics defined in
    Section 6.3, namely TCP or QUIC connections per second, inspected
    throughput, concurrent TCP or QUIC connections, and application
    transactions per second.  No measurements are made in this phase.

 Sustain phase:
    This phase starts when all required clients are active and
    operating at their desired load condition.  In the sustain phase,
    the test equipment MUST continue generating traffic to a constant
    target value for a constant number of active clients.  The minimum
    RECOMMENDED time duration for the sustain phase is 300 seconds.
    This is the phase where measurements occur.  The test equipment
    MUST measure and record statistics continuously.  The sampling
    interval for collecting the raw results and calculating the
    statistics MUST be less than 2 seconds.

 Ramp Down phase:
    The test traffic slows down from the target number to 0, and no
    measurements are made.

 Collection phase:
    The last phase is administrative and will occur when the test
    equipment merges and collates the report data.

5. Testbed Considerations

 This section describes steps for a reference test (pre-test) that
 controls the test environment, including test equipment, focusing on
 physical and virtualized environments and test equipment.  Below are
 the RECOMMENDED steps for the reference test.

 1.  Perform the reference test either by configuring the DUT/SUT in
     the most trivial setup (fast forwarding) or without the presence
     of the DUT/SUT.

 2.  Generate traffic from the traffic generator.  Choose a traffic
     profile used for the HTTP or HTTPS throughput performance test
     with the smallest object size.

 3.  Ensure that any ancillary switching or routing functions added in
     the test equipment do not limit performance by introducing packet
     loss or latency.  This is specifically important for virtualized
     components (e.g., vSwitches or vRouters).

 4.  Verify that the generated traffic (performance) of the test
     equipment matches and reasonably exceeds the expected maximum
     performance of the DUT/SUT.

 5.  Record the network performance metrics packet loss and latency
     introduced by the test environment (without the DUT/SUT).

 6.  Assert that the testbed characteristics are stable during the
     entire test session.  Several factors might influence stability,
     specifically for virtualized testbeds, for example, additional
     workloads in a virtualized system, load balancing, and movement
     of virtual machines during the test or simple issues, such as
     additional heat created by high workloads leading to an emergency
     CPU performance reduction.

 The reference test MUST be performed before the benchmarking tests
 (described in Section 7) start.

6. Reporting

 This section describes how the benchmarking test report should be
 formatted and presented.  It is RECOMMENDED to include two main
 sections in the report: the introduction and the detailed test
 results sections.

6.1. Introduction

 The following attributes should be present in the introduction
 section of the test report.

 1.  Time and date of the execution of the tests

 2.  Summary of testbed software and hardware details

     a.  DUT/SUT hardware/virtual configuration

• Make and model of the DUT/SUT, which should be clearly

identified

• Port interfaces, including speed and link information

• If the DUT/SUT is a Virtual Network Function (VNF)

• Host (server) hardware and software details

• Interface acceleration type (such as Data Plane

Development Kit (DPDK) and single-root input/output

            virtualization (SR-IOV))

• Used CPU cores

• Used RAM

• Resource sharing (e.g., pinning details and Non-Uniform

Memory Access (NUMA) node) configuration details

• Hypervisor version

• Virtual switch version

• Details of any additional hardware relevant to the DUT/

SUT, such as controllers

     b.  DUT/SUT software

• Operating system name

• Version

• Specific configuration details (if any)

     c.  DUT-/SUT-enabled features

• Configured DUT/SUT features (see Tables 2 and 3)

• Attributes of the abovementioned features

• Any additional relevant information about the features

     d.  Test equipment hardware and software

• Test equipment vendor name

• Hardware details, including model number and interface

type

• Test equipment firmware and test application software

version

• If the test equipment is a virtual solution

• The host (server) hardware and software details

• Interface acceleration type (such as DPDK and SR-IOV)

• Used CPU cores

• Used RAM

• Resource sharing (e.g., pinning details and NUMA node)

configuration details

• Hypervisor version

• Virtual switch version

     e.  Key test parameters

• Used cipher suites and keys

• IPv4 and IPv6 traffic distribution

• Number of configured ACLs

• TCP and UDP stack parameter, if tested

• QUIC, HTTP/2, and HTTP/3 parameters, if tested

     f.  Details of the application traffic mix used in the
         benchmarking test Throughput Performance with Application
         Traffic Mix (Section 7.1)

• Name of applications and layer 7 protocols

• Percentage of emulated traffic for each application and

layer 7 protocols

• Percentage of encrypted traffic, used cipher suites, and

keys (the RECOMMENDED ciphers and keys are defined in

            Section 4.3.1.4)

• Used object sizes for each application and layer 7

protocols

 3.  Results Summary / Executive Summary

     a.  Results should be presented with an introduction section
         documenting the summary of results in a prominent, easy-to-
         read block.

6.2. Detailed Test Results

 In the results section of the test report, the following attributes
 should be present for each benchmarking test.

 a.  KPIs MUST be documented separately for each benchmarking test.
     The format of the KPI metrics MUST be presented as described in
     Section 6.3.

 b.  The next level of details should be graphs showing each of these
     metrics over the duration (sustain phase) of the test.  This
     allows the user to see the measured performance stability changes
     over time.

6.3. Benchmarks and Key Performance Indicators

 This section lists key performance indicators (KPIs) for overall
 benchmarking tests.  All KPIs MUST be measured during the sustain
 phase of the traffic load profile described in Section 4.3.4.  Also,
 the KPIs MUST be measured from the result output of test equipment.

 Concurrent TCP Connections
    The aggregate number of simultaneous connections between hosts
    across the DUT/SUT or between hosts and the DUT/SUT (defined in
    [RFC2647]).

 Concurrent QUIC Connections
    The aggregate number of simultaneous connections between hosts
    across the DUT/SUT.

 TCP Connections Per Second
    The average number of successfully established TCP connections per
    second between hosts across the DUT/SUT or between hosts and the
    DUT/SUT.  As described in Section 4.3.1.1, the TCP connections are
    initiated by clients via a TCP three-way handshake (SYN, SYN/ACK,
    ACK).  Then, the TCP session data is sent, and then the TCP
    sessions are closed via either a TCP three-way close (FIN, FIN/
    ACK, ACK) or a TCP four-way close (FIN, ACK, FIN, ACK).  The TCP
    sessions MUST NOT be closed by RST.

 QUIC Connections Per Second
    The average number of successfully established QUIC connections
    per second between hosts across the DUT/SUT.  As described in
    Section 4.3.1.2, the QUIC connections are initiated by clients.
    Then, the data is sent, and then the QUIC sessions are closed by
    the "immediate close" method.

    Since the QUIC specification defined in Section 4.3.1.2 recommends
    disabling 0-RTT and early data, this KPI is focused on the 1-RTT
    handshake.  If required, 0-RTT can be also measured in separate
    test runs while enabling 0-RTT and early data in the test
    equipment.

 Application Transactions Per Second
    The average number of successfully completed transactions per
    second.  For a particular transaction to be considered successful,
    all data MUST have been transferred in its entirety.  In case of
    an HTTP(S) transaction, it MUST have a valid status code (200 OK).

 TLS Handshake Rate
    The average number of successfully established TLS connections per
    second between hosts across the DUT/SUT or between hosts and the
    DUT/SUT.

    For TLS 1.3, the handshake rate can be measured with the 0-RTT or
    1-RTT handshake.  The transport protocol can be either TCP or
    QUIC.

 Inspected Throughput
    The number of bits per second of examined and allowed traffic a
    network security device is able to transmit to the correct
    destination interface(s) in response to a specified offered load.
    The throughput benchmarking tests defined in Section 7 SHOULD
    measure the average layer 2 throughput value when the DUT/SUT is
    "inspecting" traffic.  It is also acceptable to measure other OSI
    layer throughput.  However, the measured layer (e.g., layer 3
    throughput) MUST be noted in the report, and the user MUST be
    aware of the implication while comparing the throughput
    performance of multiple DUTs/SUTs measured in different OSI
    layers.  This document recommends presenting the inspected
    throughput value in Gbit/s rounded to two places of precision with
    a more specific kbit/s in parenthesis.

 Time to First Byte (TTFB)
    The elapsed time between the start of sending the TCP SYN packet
    or QUIC initial Client Hello from the client and the client
    receiving the first packet of application data from the server via
    the DUT/SUT.  The benchmarking tests HTTP transaction latency
    (Section 7.4) and HTTPS transaction latency (Section 7.8) measure
    the minimum, average, and maximum TTFB.  The value should be
    expressed in milliseconds.

 URL Response Time / Time to Last Byte (TTLB)
    The elapsed time between the start of sending the TCP SYN packet
    or QUIC initial Client Hello from the client and the client
    receiving the last packet of application data from the server via
    the DUT/SUT.  The benchmarking tests HTTP transaction latency
    (Section 7.4) and HTTPS transaction latency (Section 7.8) measure
    the minimum, average, and maximum TTLB.  The value should be
    expressed in milliseconds.

7. Benchmarking Tests

 This section mainly focuses on the benchmarking tests with HTTP/1.1
 or HTTP/2 traffic, which uses TCP as the transport protocol.  In
 particular, this section does not define specific benchmarking tests
 for KPIs related to QUIC or HTTP/3.  However, the test methodology
 defined in the benchmarking tests TCP or QUIC connections per second
 with HTTPS traffic (Section 7.6), HTTPS transaction latency
 (Section 7.8), HTTPS throughput (Section 7.7), and concurrent TCP or
 QUIC connection capacity with HTTPS traffic (Section 7.9) can be used
 to test KPIs related to QUIC or HTTP/3.  The throughput performance
 test with the application traffic mix defined in Section 7.1 can be
 performed with any other application traffic, including HTTP/3.

7.1. Throughput Performance with Application Traffic Mix

7.1.1. Objective

 Using a relevant application traffic mix, determine the sustainable
 inspected throughput supported by the DUT/SUT.

 Based on the test customer's specific use case, testers can choose
 the relevant application traffic mix for this test.  The details
 about the traffic mix MUST be documented in the report.  At least,
 the following traffic mix details MUST be documented and reported
 together with the test results:

• Name of applications and layer 7 protocols

• Percentage of emulated traffic for each application and layer 7

protocol

• Percentage of encrypted traffic and used cipher suites and keys

(the RECOMMENDED ciphers and keys are defined in Section 4.3.1.4)

• Used object sizes for each application and layer 7 protocols

7.1.2. Test Setup

 The testbed setup MUST be configured as defined in Section 4.  Any
 benchmarking-test-specific testbed configuration changes MUST be
 documented.

7.1.3. Test Parameters

 In this section, the benchmarking-test-specific parameters are
 defined.

7.1.3.1. DUT/SUT Configuration Parameters

 DUT/SUT parameters MUST conform to the requirements defined in
 Section 4.2.  Any configuration changes for this specific
 benchmarking test MUST be documented.  If the DUT/SUT is configured
 without TLS inspection, the test report MUST explain how this impacts
 the encrypted traffic of the relevant application traffic mix.

7.1.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The following parameters MUST
 be documented for this benchmarking test:

• Client IP address ranges defined in Section 4.3.1.3

• Server IP address ranges defined in Section 4.3.2.3

• Traffic distribution ratio between IPv4 and IPv6 defined in

Section 4.3.1.3

• Target inspected throughput: Aggregated line rate of one or more

interfaces used in the DUT/SUT or the value defined based on the

    requirement for a specific deployment scenario

• Initial throughput: 10% of the "Target inspected throughput"

    Note: Initial throughput is not a KPI to report.  This value is
    configured on the traffic generator and used to perform Step 1
    (Test Initialization and Qualification) described in
    Section 7.1.4.

• One of the ciphers and keys defined in Section 4.3.1.4 is

RECOMMENDED to use for this benchmarking test.

7.1.3.3. Traffic Profile

 This test MUST be run with a relevant application traffic mix
 profile.

7.1.3.4. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 sustain phase of the traffic load profile.

 a.  The number of failed application transactions MUST be less than
     0.001% (1 out of 100,000 transactions) of the attempted
     transactions.

 b.  The number of terminated TCP connections due to unexpected TCP
     RST sent by the DUT/SUT MUST be less than 0.001% (1 out of
     100,000 connections) of the total initiated TCP connections.

 c.  If HTTP/3 is used, the number of failed QUIC connections due to
     unexpected HTTP/3 error codes MUST be less than 0.001% (1 out of
     100,000 connections) of the total initiated QUIC connections.

7.1.3.5. Measurement

 The following KPI metrics MUST be reported for this benchmarking
 test:

• Mandatory KPIs (benchmarks): inspected throughput and application

transactions per second

    Note: The TTLB MUST be reported along with the object size used in
    the traffic profile.

• Optional TCP-stack-related KPIs: TCP connections per second, TLS

handshake rate, TTFB (minimum, average, and maximum), TTLB

    (minimum, average, and maximum)

• Optional QUIC-stack-related KPIs: QUIC connections per second and

concurrent QUIC connections

7.1.4. Test Procedures and Expected Results

 The test procedures are designed to measure the inspected throughput
 performance of the DUT/SUT at the sustaining period of the traffic
 load profile.  The test procedure consists of three major steps.
 Step 1 ensures the DUT/SUT is able to reach the performance value
 (initial throughput) and meets the test results validation criteria
 when it was very minimally utilized.  Step 2 determines whether the
 DUT/SUT is able to reach the target performance value within the test
 results validation criteria.  Step 3 determines the maximum
 achievable performance value within the test results validation
 criteria.

 This test procedure MAY be repeated multiple times with different IP
 types: IPv4 only, IPv6 only, and IPv4 and IPv6 mixed traffic
 distribution.

7.1.4.1. Step 1: Test Initialization and Qualification

 Verify the link status of all connected physical interfaces.  All
 interfaces are expected to be in "UP" status.

 Configure the traffic load profile of the test equipment to generate
 test traffic at the "initial throughput" rate, as described in
 Section 7.1.3.2.  The test equipment MUST follow the traffic load
 profile definition described in Section 4.3.4.  The DUT/SUT MUST
 reach the "initial throughput" during the sustain phase.  Measure all
 KPIs, as defined in Section 7.1.3.5.  The measured KPIs during the
 sustain phase MUST meet all the test results validation criteria
 defined in Section 7.1.3.4.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT be continued to Step 2.

7.1.4.2. Step 2: Test Run with Target Objective

 Configure test equipment to generate traffic at the "Target inspected
 throughput" rate defined in Section 7.1.3.2.  The test equipment MUST
 follow the traffic load profile definition described in
 Section 4.3.4.  The test equipment MUST start to measure and record
 all specified KPIs.  Continue the test until all traffic profile
 phases are completed.

 Within the test results validation criteria, the DUT/SUT is expected
 to reach the desired value of the target objective ("Target inspected
 throughput") in the sustain phase.  Follow Step 3 if the measured
 value does not meet the target value or does not fulfill the test
 results validation criteria.

7.1.4.3. Step 3: Test Iteration

 Determine the achievable average inspected throughput within the test
 results validation criteria.  The final test iteration MUST be
 performed for the test duration defined in Section 4.3.4.

7.2. TCP Connections Per Second with HTTP Traffic

7.2.1. Objective

 Using HTTP traffic, determine the sustainable TCP connection
 establishment rate supported by the DUT/SUT under different
 throughput load conditions.

 To measure connections per second, test iterations MUST use different
 fixed HTTP response object sizes (the different load conditions)
 defined in Section 7.2.3.2.

7.2.2. Test Setup

 The testbed setup MUST be configured as defined in Section 4.  Any
 specific testbed configuration changes (number of interfaces,
 interface type, etc.)  MUST be documented.

7.2.3. Test Parameters

 In this section, benchmarking-test-specific parameters are defined.

7.2.3.1. DUT/SUT Configuration Parameters

 DUT/SUT parameters MUST conform to the requirements defined in
 Section 4.2.  Any configuration changes for this specific
 benchmarking test MUST be documented.

7.2.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The following parameters MUST
 be documented for this benchmarking test:

• Client IP address ranges defined in Section 4.3.1.3

• Server IP address ranges defined in Section 4.3.2.3

• Traffic distribution ratio between IPv4 and IPv6 defined in

Section 4.3.1.3

• Target connections per second: Initial value from the product

datasheet or the value defined based on the requirement for a

    specific deployment scenario

• Initial connections per second: 10% of "Target connections per

second"

    Note: Initial connections per second is not a KPI to report.  This
    value is configured on the traffic generator and used to perform
    Step 1 (Test Initialization and Qualification) described in
    Section 7.2.4.

• The RECOMMENDED response object sizes are 1, 2, 4, 16, and 64 KB.

 The client MUST negotiate HTTP and close the connection with FIN
 immediately after the completion of one transaction.  In each test
 iteration, the client MUST send a GET request requesting a fixed HTTP
 response object size.

7.2.3.3. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 sustain phase of the traffic load profile.

 a.  The number of failed application transactions (receiving any HTTP
     response code other than 200 OK) MUST be less than 0.001% (1 out
     of 100,000 transactions) of the attempted transactions.

 b.  The number of terminated TCP connections due to unexpected TCP
     RST sent by the DUT/SUT MUST be less than 0.001% (1 out of
     100,000 connections) of the total initiated TCP connections.

 c.  During the sustain phase, traffic MUST be forwarded at a constant
     rate (it is considered as a constant rate if any deviation of the
     traffic forwarding rate is less than 5%).

 d.  Concurrent TCP connections MUST be constant during steady state,
     and any deviation of concurrent TCP connections MUST be less than
     10%. This confirms the DUT opens and closes TCP connections at
     approximately the same rate.

7.2.3.4. Measurement

 TCP connections per second MUST be reported for each test iteration
 (for each object size).

7.2.4. Test Procedures and Expected Results

 The test procedure is designed to measure the DUT/SUT's rate of TCP
 connections per second during the sustaining period of the traffic
 load profile.  The test procedure consists of three major steps.
 Step 1 ensures the DUT/SUT is able to reach the performance value
 (Initial connections per second) and meets the test results
 validation criteria when it was very minimally utilized.  Step 2
 determines whether the DUT/SUT is able to reach the target
 performance value within the test results validation criteria.  Step
 3 determines the maximum achievable performance value within the test
 results validation criteria.

 This test procedure MAY be repeated multiple times with different IP
 types: IPv4 only, IPv6 only, and IPv4 and IPv6 mixed traffic
 distribution.

7.2.4.1. Step 1: Test Initialization and Qualification

 Verify the link status of all connected physical interfaces.  All
 interfaces are expected to be in "UP" status.

 Configure the traffic load profile of the test equipment to establish
 "Initial connections per second", as defined in Section 7.2.3.2.  The
 traffic load profile MUST be defined as described in Section 4.3.4.

 The DUT/SUT MUST reach the "Initial connections per second" before
 the sustain phase.  The measured KPIs during the sustain phase MUST
 meet all the test results validation criteria defined in
 Section 7.2.3.3.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT continue to Step 2.

7.2.4.2. Step 2: Test Run with Target Objective

 Configure test equipment to establish the target objective ("Target
 connections per second") defined in Section 7.2.3.2.  The test
 equipment MUST follow the traffic load profile definition described
 in Section 4.3.4.

 During the ramp up and sustain phases of each test iteration, other
 KPIs, such as inspected throughput, concurrent TCP connections, and
 application transactions per second, MUST NOT reach the maximum value
 the DUT/SUT can support.  The test results for specific test
 iterations MUST NOT be reported as valid results if the
 abovementioned KPI (especially inspected throughput) reaches the
 maximum value.  (For example, if the test iteration with 64 KB of
 HTTP response object size reached the maximum inspected throughput
 limitation of the DUT/SUT, the test iteration MAY be interrupted and
 the result for 64 KB must not be reported.)

 The test equipment MUST start to measure and record all specified
 KPIs.  Continue the test until all traffic profile phases are
 completed.

 Within the test results validation criteria, the DUT/SUT is expected
 to reach the desired value of the target objective ("Target
 connections per second") in the sustain phase.  Follow Step 3 if the
 measured value does not meet the target value or does not fulfill the
 test results validation criteria.

7.2.4.3. Step 3: Test Iteration

 Determine the achievable TCP connections per second within the test
 results validation criteria.

7.3. HTTP Throughput

7.3.1. Objective

 Determine the sustainable inspected throughput of the DUT/SUT for
 HTTP transactions varying the HTTP response object size.

7.3.2. Test Setup

 The testbed setup MUST be configured as defined in Section 4.  Any
 specific testbed configuration changes (number of interfaces,
 interface type, etc.)  MUST be documented.

7.3.3. Test Parameters

 In this section, benchmarking-test-specific parameters are defined.

7.3.3.1. DUT/SUT Configuration Parameters

 DUT/SUT parameters MUST conform to the requirements defined in
 Section 4.2.  Any configuration changes for this specific
 benchmarking test MUST be documented.

7.3.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The following parameters MUST
 be documented for this benchmarking test:

• Client IP address ranges defined in Section 4.3.1.3

• Server IP address ranges defined in Section 4.3.2.3

• Traffic distribution ratio between IPv4 and IPv6 defined in

Section 4.3.1.3

• Target inspected throughput: Aggregated line rate of one or more

interfaces used in the DUT/SUT or the value defined based on the

    requirement for a specific deployment scenario

• Initial throughput: 10% of "Target inspected throughput"

    Note: Initial throughput is not a KPI to report.  This value is
    configured on the traffic generator and used to perform Step 1
    (Test Initialization and Qualification) described in
    Section 7.3.4.

• Number of HTTP response object requests (transactions) per

connection: 10

• RECOMMENDED HTTP response object size: 1, 16, 64, and 256 KB and

mixed objects defined in Table 5

          +==================+=============================+
          | Object size (KB) | Number of requests / Weight |
          +==================+=============================+
          | 0.2              | 1                           |
          +------------------+-----------------------------+
          | 6                | 1                           |
          +------------------+-----------------------------+
          | 8                | 1                           |
          +------------------+-----------------------------+
          | 9                | 1                           |
          +------------------+-----------------------------+
          | 10               | 1                           |
          +------------------+-----------------------------+
          | 25               | 1                           |
          +------------------+-----------------------------+
          | 26               | 1                           |
          +------------------+-----------------------------+
          | 35               | 1                           |
          +------------------+-----------------------------+
          | 59               | 1                           |
          +------------------+-----------------------------+
          | 347              | 1                           |
          +------------------+-----------------------------+

                        Table 5: Mixed Objects

7.3.3.3. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 sustain phase of the traffic load profile.

 a.  The number of failed application transactions (receiving any HTTP
     response code other than 200 OK) MUST be less than 0.001% (1 out
     of 100,000 transactions) of the total attempted transactions.

 b.  Traffic MUST be forwarded at a constant rate (it is considered as
     a constant rate if any deviation of the traffic forwarding rate
     is less than 5%).

 c.  Concurrent TCP connections MUST be constant during steady state,
     and any deviation of concurrent TCP connections MUST be less than
     10%. This confirms the DUT opens and closes TCP connections at
     approximately the same rate.

7.3.3.4. Measurement

 Inspected throughput and HTTP transactions per second MUST be
 reported for each object size.

7.3.4. Test Procedures and Expected Results

 The test procedure is designed to measure HTTP throughput of the DUT/
 SUT.  The test procedure consists of three major steps.  Step 1
 ensures the DUT/SUT is able to reach the performance value (initial
 throughput) and meets the test results validation criteria when it
 was very minimally utilized.  Step 2 determines whether the DUT/SUT
 is able to reach the target performance value within the test results
 validation criteria.  Step 3 determines the maximum achievable
 performance value within the test results validation criteria.

 This test procedure MAY be repeated multiple times with different
 IPv4 and IPv6 traffic distributions and HTTP response object sizes.

7.3.4.1. Step 1: Test Initialization and Qualification

 Verify the link status of all connected physical interfaces.  All
 interfaces are expected to be in "UP" status.

 Configure the traffic load profile of the test equipment to establish
 "initial throughput", as defined in Section 7.3.3.2.

 The traffic load profile MUST be defined as described in
 Section 4.3.4.  The DUT/SUT MUST reach the "initial throughput"
 during the sustain phase.  Measure all KPIs, as defined in
 Section 7.3.3.4.

 The measured KPIs during the sustain phase MUST meet the test results
 validation criteria "a" defined in Section 7.3.3.3.  The test results
 validation criteria "b" and "c" are OPTIONAL for Step 1.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT be continued to Step 2.

7.3.4.2. Step 2: Test Run with Target Objective

 Configure test equipment to establish the target objective ("Target
 inspected throughput") defined in Section 7.3.3.2.  The test
 equipment MUST start to measure and record all specified KPIs.
 Continue the test until all traffic profile phases are completed.

 Within the test results validation criteria, the DUT/SUT is expected
 to reach the desired value of the target objective in the sustain
 phase.  Follow Step 3 if the measured value does not meet the target
 value or does not fulfill the test results validation criteria.

7.3.4.3. Step 3: Test Iteration

 Determine the achievable inspected throughput within the test results
 validation criteria and measure the KPI metric transactions per
 second.  The final test iteration MUST be performed for the test
 duration defined in Section 4.3.4.

7.4. HTTP Transaction Latency

7.4.1. Objective

 Using HTTP traffic, determine the HTTP transaction latency when the
 DUT is running with sustainable HTTP transactions per second
 supported by the DUT/SUT under different HTTP response object sizes.

 Test iterations MUST be performed with different HTTP response object
 sizes in two different scenarios: one with a single transaction and
 the other with multiple transactions within a single TCP connection.
 For consistency, both the single and multiple transaction tests MUST
 be configured with the same HTTP version.

 Scenario 1: The client MUST negotiate HTTP and close the connection
 with FIN immediately after the completion of a single transaction
 (GET and RESPONSE).

 Scenario 2: The client MUST negotiate HTTP and close the connection
 with FIN immediately after the completion of 10 transactions (GET and
 RESPONSE) within a single TCP connection.

7.4.2. Test Setup

 The testbed setup MUST be configured as defined in Section 4.  Any
 specific testbed configuration changes (number of interfaces,
 interface type, etc.)  MUST be documented.

7.4.3. Test Parameters

 In this section, benchmarking-test-specific parameters are defined.

7.4.3.1. DUT/SUT Configuration Parameters

 DUT/SUT parameters MUST conform to the requirements defined in
 Section 4.2.  Any configuration changes for this specific
 benchmarking test MUST be documented.

7.4.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The following parameters MUST
 be documented for this benchmarking test:

• Client IP address ranges defined in Section 4.3.1.3

• Server IP address ranges defined in Section 4.3.2.3

• Traffic distribution ratio between IPv4 and IPv6 defined in

Section 4.3.1.3

• Target objective for scenario 1: 50% of the connections per second

measured in the benchmarking test TCP connections per second with

    HTTP traffic (Section 7.2)

• Target objective for scenario 2: 50% of the inspected throughput

measured in the benchmarking test HTTP throughput (Section 7.3)

• Initial objective for scenario 1: 10% of "Target objective for

scenario 1"

• Initial objective for scenario 2: 10% of "Target objective for

scenario 2"

    Note: The initial objectives are not KPIs to report.  These values
    are configured on the traffic generator and used to perform Step 1
    (Test Initialization and Qualification) described in
    Section 7.4.4.

• HTTP transaction per TCP connection: Test scenario 1 with a single

transaction and test scenario 2 with 10 transactions

• HTTP with GET request requesting a single object: The RECOMMENDED

object sizes are 1, 16, and 64 KB. For each test iteration, the

    client MUST request a single HTTP response object size.

7.4.3.3. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 sustain phase of the traffic load profile.

 a.  The number of failed application transactions (receiving any HTTP
     response code other than 200 OK) MUST be less than 0.001% (1 out
     of 100,000 transactions) of the total attempted transactions.

 b.  The number of terminated TCP connections due to unexpected TCP
     RST sent by the DUT/SUT MUST be less than 0.001% (1 out of
     100,000 connections) of the total initiated TCP connections.

 c.  During the sustain phase, traffic MUST be forwarded at a constant
     rate (it is considered as a constant rate if any deviation of the
     traffic forwarding rate is less than 5%).

 d.  Concurrent TCP connections MUST be constant during steady state,
     and any deviation of concurrent TCP connections MUST be less than
     10%. This confirms the DUT opens and closes TCP connections at
     approximately the same rate.

 e.  After ramp up, the DUT MUST achieve the target objectives defined
     in Section 7.4.3.2 and remain in that state for the entire test
     duration (sustain phase).

7.4.3.4. Measurement

 The TTFB (minimum, average, and maximum) and TTLB (minimum, average,
 and maximum) MUST be reported for each object size.

7.4.4. Test Procedures and Expected Results

 The test procedure is designed to measure the TTFB or TTLB when the
 DUT/SUT is operating close to 50% of its maximum achievable
 connections per second or inspected throughput.  The test procedure
 consists of two major steps.  Step 1 ensures the DUT/SUT is able to
 reach the initial performance values and meets the test results
 validation criteria when it was very minimally utilized.  Step 2
 measures the latency values within the test results validation
 criteria.

 This test procedure MAY be repeated multiple times with different IP
 types (IPv4 only, IPv6 only, and IPv4 and IPv6 mixed traffic
 distribution), HTTP response object sizes, and single and multiple
 transactions per connection scenarios.

7.4.4.1. Step 1: Test Initialization and Qualification

 Verify the link status of all connected physical interfaces.  All
 interfaces are expected to be in "UP" status.

 Configure the traffic load profile of the test equipment to establish
 the initial objectives, as defined in Section 7.4.3.2.  The traffic
 load profile MUST be defined as described in Section 4.3.4.

 The DUT/SUT MUST reach the initial objectives before the sustain
 phase.  The measured KPIs during the sustain phase MUST meet all the
 test results validation criteria defined in Section 7.4.3.3.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT be continued to Step 2.

7.4.4.2. Step 2: Test Run with Target Objective

 Configure test equipment to establish the target objectives defined
 in Section 7.4.3.2.  The test equipment MUST follow the traffic load
 profile definition described in Section 4.3.4.

 The test equipment MUST start to measure and record all specified
 KPIs.  Continue the test until all traffic profile phases are
 completed.

 Within the test results validation criteria, the DUT/SUT MUST reach
 the desired value of the target objective in the sustain phase.

 Measure the minimum, average, and maximum values of the TTFB and
 TTLB.

7.5. Concurrent TCP Connection Capacity with HTTP Traffic

7.5.1. Objective

 Determine the number of concurrent TCP connections that the DUT/SUT
 sustains when using HTTP traffic.

7.5.2. Test Setup

 The testbed setup MUST be configured as defined in Section 4.  Any
 specific testbed configuration changes (number of interfaces,
 interface type, etc.)  MUST be documented.

7.5.3. Test Parameters

 In this section, benchmarking-test-specific parameters are defined.

7.5.3.1. DUT/SUT Configuration Parameters

 DUT/SUT parameters MUST conform to the requirements defined in
 Section 4.2.  Any configuration changes for this specific
 benchmarking test MUST be documented.

7.5.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The following parameters MUST
 be noted for this benchmarking test:

• Client IP address ranges defined in Section 4.3.1.3

• Server IP address ranges defined in Section 4.3.2.3

• Traffic distribution ratio between IPv4 and IPv6 defined in

Section 4.3.1.3

• Target concurrent connection: Initial value from the product

datasheet or the value defined based on the requirement for a

    specific deployment scenario

• Initial concurrent connection: 10% of "Target concurrent

connection"

    Note: Initial concurrent connection is not a KPI to report.  This
    value is configured on the traffic generator and used to perform
    Step 1 (Test Initialization and Qualification) described in
    Section 7.5.4.

• Maximum connections per second during ramp up phase: 50% of

maximum connections per second measured in the benchmarking test

    TCP connections per second with HTTP traffic (Section 7.2)

• Ramp up time (in traffic load profile for "Target concurrent

connection"): "Target concurrent connection" / "Maximum

    connections per second during ramp up phase"

• Ramp up time (in traffic load profile for "Initial concurrent

connection"): "Initial concurrent connection" / "Maximum

    connections per second during ramp up phase"

 The client MUST negotiate HTTP, and each client MAY open multiple
 concurrent TCP connections per server endpoint IP.

 Each client sends 10 GET requests requesting 1 KB HTTP response
 object in the same TCP connection (10 transactions / TCP
 connections), and the delay (think time) between each transaction
 MUST be X seconds, where X is as follows.

    X = ("Ramp up time" + "steady state time") / 10

 The established connections MUST remain open until the ramp down
 phase of the test.  During the ramp down phase, all connections MUST
 be successfully closed with FIN.

7.5.3.3. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 sustain phase of the traffic load profile.

 a.  The number of failed application transactions (receiving any HTTP
     response code other than 200 OK) MUST be less than 0.001% (1 out
     of 100,000 transactions) of the total attempted transactions.

 b.  The number of terminated TCP connections due to unexpected TCP
     RST sent by the DUT/SUT MUST be less than 0.001% (1 out of
     100,000 connections) of the total initiated TCP connections.

 c.  During the sustain phase, traffic MUST be forwarded at a constant
     rate (it is considered as a constant rate if any deviation of the
     traffic forwarding rate is less than 5%).

7.5.3.4. Measurement

 Average concurrent TCP connections MUST be reported for this
 benchmarking test.

7.5.4. Test Procedures and Expected Results

 The test procedure is designed to measure the concurrent TCP
 connection capacity of the DUT/SUT at the sustaining period of the
 traffic load profile.  The test procedure consists of three major
 steps.  Step 1 ensures the DUT/SUT is able to reach the performance
 value (Initial concurrent connection) and meets the test results
 validation criteria when it was very minimally utilized.  Step 2
 determines whether the DUT/SUT is able to reach the target
 performance value within the test results validation criteria.  Step
 3 determines the maximum achievable performance value within the test
 results validation criteria.

 This test procedure MAY be repeated multiple times with different
 IPv4 and IPv6 traffic distributions.

7.5.4.1. Step 1: Test Initialization and Qualification

 Verify the link status of all connected physical interfaces.  All
 interfaces are expected to be in "UP" status.

 Configure test equipment to establish "Initial concurrent
 connections" defined in Section 7.5.3.2.  Except ramp up time, the
 traffic load profile MUST be defined as described in Section 4.3.4.

 During the sustain phase, the DUT/SUT MUST reach the "Initial
 concurrent connections".  The measured KPIs during the sustain phase
 MUST meet all the test results validation criteria defined in
 Section 7.5.3.3.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT be continued to Step 2.

7.5.4.2. Step 2: Test Run with Target Objective

 Configure test equipment to establish the target objective ("Target
 concurrent TCP connections").  The test equipment MUST follow the
 traffic load profile definition (except ramp up time) as described in
 Section 4.3.4.

 During the ramp up and sustain phases, the other KPIs, such as
 inspected throughput, TCP connections per second, and application
 transactions per second, MUST NOT reach the maximum value the DUT/SUT
 can support.

 The test equipment MUST start to measure and record KPIs defined in
 Section 7.5.3.4.  Continue the test until all traffic profile phases
 are completed.

 Within the test results validation criteria, the DUT/SUT is expected
 to reach the desired value of the target objective in the sustain
 phase.  Follow Step 3 if the measured value does not meet the target
 value or does not fulfill the test results validation criteria.

7.5.4.3. Step 3: Test Iteration

 Determine the achievable concurrent TCP connections capacity within
 the test results validation criteria.

7.6. TCP or QUIC Connections per Second with HTTPS Traffic

7.6.1. Objective

 Using HTTPS traffic, determine the sustainable TLS session
 establishment rate supported by the DUT/SUT under different
 throughput load conditions.

 Test iterations MUST include common cipher suites and key strengths,
 as well as forward-looking stronger keys.  Specific test iterations
 MUST include ciphers and keys defined in Section 7.6.3.2.

 For each cipher suite and key strength, test iterations MUST use a
 single HTTPS response object size defined in Section 7.6.3.2 to
 measure connections per second performance under a variety of DUT/SUT
 security inspection load conditions.

7.6.2. Test Setup

 The testbed setup MUST be configured as defined in Section 4.  Any
 specific testbed configuration changes (number of interfaces,
 interface type, etc.)  MUST be documented.

7.6.3. Test Parameters

 In this section, benchmarking-test-specific parameters are defined.

7.6.3.1. DUT/SUT Configuration Parameters

 DUT/SUT parameters MUST conform to the requirements defined in
 Section 4.2.  Any configuration changes for this specific
 benchmarking test MUST be documented.

7.6.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The following parameters MUST
 be documented for this benchmarking test:

• Client IP address ranges defined in Section 4.3.1.3

• Server IP address ranges defined in Section 4.3.2.3

• Traffic distribution ratio between IPv4 and IPv6 defined in

Section 4.3.1.3

• Target connections per second: Initial value from the product

datasheet or the value defined based on the requirement for a

    specific deployment scenario

• Initial connections per second: 10% of "Target connections per

second"

    Note: Initial connections per second is not a KPI to report.  This
    value is configured on the traffic generator and used to perform
    Step 1 (Test Initialization and Qualification) described in
    Section 7.6.4.)

• RECOMMENDED ciphers and keys defined in Section 4.3.1.4

• The RECOMMENDED object sizes are 1, 2, 4, 16, and 64 KB.

 The client MUST negotiate HTTPS and close the connection without
 error immediately after the completion of one transaction.  In each
 test iteration, the client MUST send a GET request requesting a fixed
 HTTPS response object size.

7.6.3.3. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 test duration.

 a.  The number of failed application transactions (receiving any HTTP
     response code other than 200 OK) MUST be less than 0.001% (1 out
     of 100,000 transactions) of the attempted transactions.

 b.  The number of terminated TCP connections due to unexpected TCP
     RST sent by the DUT/SUT MUST be less than 0.001% (1 out of
     100,000 connections) of the total initiated TCP connections.  If
     HTTP/3 is used, the number of terminated QUIC connections due to
     unexpected errors MUST be less than 0.001% (1 out of 100,000
     connections) of the total initiated QUIC connections.

 c.  During the sustain phase, traffic MUST be forwarded at a constant
     rate (it is considered as a constant rate if any deviation of the
     traffic forwarding rate is less than 5%).

 d.  The concurrent TCP connections generation rate MUST be constant
     during steady state, and any deviation of concurrent TCP
     connections MUST be less than 10%. If HTTP/3 is used, the
     concurrent QUIC connections generation rate MUST be constant
     during steady state, and any deviation of concurrent QUIC
     connections MUST be less than 10%. This confirms the DUT opens
     and closes connections at approximately the same rate.

7.6.3.4. Measurement

 If HTTP 1.1 or HTTP/2 is used, TCP connections per second MUST be
 reported for each test iteration (for each object size).

 If HTTP/3 is used, QUIC connections per second MUST be measured and
 reported for each test iteration (for each object size).

 The KPI metric TLS handshake rate can be measured in the test using 1
 KB object size.

7.6.4. Test Procedures and Expected Results

 The test procedure is designed to measure the DUT/SUT's rate of TCP
 or QUIC connections per second during the sustaining period of the
 traffic load profile.  The test procedure consists of three major
 steps.  Step 1 ensures the DUT/SUT is able to reach the performance
 value (Initial connections per second) and meets the test results
 validation criteria when it was very minimally utilized.  Step 2
 determines whether the DUT/SUT is able to reach the target
 performance value within the test results validation criteria.  Step
 3 determines the maximum achievable performance value within the test
 results validation criteria.

 This test procedure MAY be repeated multiple times with different
 IPv4 and IPv6 traffic distributions.

7.6.4.1. Step 1: Test Initialization and Qualification

 Verify the link status of all connected physical interfaces.  All
 interfaces are expected to be in "UP" status.

 Configure the traffic load profile of the test equipment to establish
 "Initial connections per second", as defined in Section 7.6.3.2.  The
 traffic load profile MUST be defined as described in Section 4.3.4.

 The DUT/SUT MUST reach the "Initial connections per second" before
 the sustain phase.  The measured KPIs during the sustain phase MUST
 meet all the test results validation criteria defined in
 Section 7.6.3.3.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT be continued to Step 2.

7.6.4.2. Step 2: Test Run with Target Objective

 Configure test equipment to establish "Target connections per
 second", as defined in Section 7.6.3.2.  The test equipment MUST
 follow the traffic load profile definition described in
 Section 4.3.4.

 During the ramp up and sustain phases, other KPIs, such as inspected
 throughput, concurrent TCP or QUIC connections, and application
 transactions per second, MUST NOT reach the maximum value the DUT/SUT
 can support.  The test results for the specific test iteration MUST
 NOT be reported as valid results if the abovementioned KPI
 (especially inspected throughput) reaches the maximum value.  (For
 example, if the test iteration with 64 KB of HTTPS response object
 size reached the maximum inspected throughput limitation of the DUT,
 the test iteration MAY be interrupted, and the result for 64 KB
 should not be reported).

 The test equipment MUST start to measure and record all specified
 KPIs.  Continue the test until all traffic profile phases are
 completed.

 Within the test results validation criteria, the DUT/SUT is expected
 to reach the desired value of the target objective ("Target
 connections per second") in the sustain phase.  Follow Step 3 if the
 measured value does not meet the target value or does not fulfill the
 test results validation criteria.

7.6.4.3. Step 3: Test Iteration

 Determine the achievable connections per second within the test
 results validation criteria.

7.7. HTTPS Throughput

7.7.1. Objective

 Determine the sustainable inspected throughput of the DUT/SUT for
 HTTPS transactions by varying the HTTPS response object size.

 Test iterations MUST include common cipher suites and key strengths,
 as well as forward-looking stronger keys.  Specific test iterations
 MUST include the ciphers and keys defined in Section 7.7.3.2.

7.7.2. Test Setup

 The testbed setup MUST be configured as defined in Section 4.  Any
 specific testbed configuration changes (number of interfaces,
 interface type, etc.)  MUST be documented.

7.7.3. Test Parameters

 In this section, benchmarking-test-specific parameters are defined.

7.7.3.1. DUT/SUT Configuration Parameters

 DUT/SUT parameters MUST conform to the requirements defined in
 Section 4.2.  Any configuration changes for this specific
 benchmarking test MUST be documented.

7.7.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The following parameters MUST
 be documented for this benchmarking test:

• Client IP address ranges defined in Section 4.3.1.3

• Server IP address ranges defined in Section 4.3.2.3

• Traffic distribution ratio between IPv4 and IPv6 defined in

Section 4.3.1.3

• Target inspected throughput: Aggregated line rate of one or more

interfaces used in the DUT/SUT or the value defined based on the

    requirement for a specific deployment scenario

• Initial throughput: 10% of "Target inspected throughput"

    Note: Initial throughput is not a KPI to report.  This value is
    configured on the traffic generator and used to perform Step 1
    (Test Initialization and Qualification) described in
    Section 7.7.4.

• Number of HTTPS response object requests (transactions) per

connection: 10

• RECOMMENDED ciphers and keys defined in Section 4.3.1.4

• RECOMMENDED HTTPS response object size: 1, 16, 64, and 256 KB and

mixed objects defined in Table 5 of Section 7.3.3.2

7.7.3.3. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 sustain phase of the traffic load profile.

 a.  The number of failed application transactions (receiving any HTTP
     response code other than 200 OK) MUST be less than 0.001% (1 out
     of 100,000 transactions) of the attempted transactions.

 b.  Traffic MUST be generated at a constant rate (it is considered as
     a constant rate if any deviation of the traffic forwarding rate
     is less than 5%).

 c.  The concurrent generated TCP connections MUST be constant during
     steady state, and any deviation of concurrent TCP connections
     MUST be less than 10%. If HTTP/3 is used, the concurrent
     generated QUIC connections MUST be constant during steady state,
     and any deviation of concurrent QUIC connections MUST be less
     than 10%. This confirms the DUT opens and closes connections at
     approximately the same rate.

7.7.3.4. Measurement

 Inspected throughput and HTTPS transactions per second MUST be
 reported for each object size.

7.7.4. Test Procedures and Expected Results

 The test procedure consists of three major steps.  Step 1 ensures the
 DUT/SUT is able to reach the performance value (initial throughput)
 and meets the test results validation criteria when it was very
 minimally utilized.  Step 2 determines whether the DUT/SUT is able to
 reach the target performance value within the test results validation
 criteria.  Step 3 determines the maximum achievable performance value
 within the test results validation criteria.

 This test procedure MAY be repeated multiple times with different
 IPv4 and IPv6 traffic distributions and HTTPS response object sizes.

7.7.4.1. Step 1: Test Initialization and Qualification

 Verify the link status of all connected physical interfaces.  All
 interfaces are expected to be in "UP" status.

 Configure the traffic load profile of the test equipment to establish
 "initial throughput", as defined in Section 7.7.3.2.

 The traffic load profile MUST be defined as described in
 Section 4.3.4.  The DUT/SUT MUST reach the "initial throughput"
 during the sustain phase.  Measure all KPIs, as defined in
 Section 7.7.3.4.

 The measured KPIs during the sustain phase MUST meet the test results
 validation criteria "a" defined in Section 7.7.3.3.  The test results
 validation criteria "b" and "c" are OPTIONAL for Step 1.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT be continued to Step 2.

7.7.4.2. Step 2: Test Run with Target Objective

 Configure test equipment to establish the target objective ("Target
 inspected throughput") defined in Section 7.7.3.2.  The test
 equipment MUST start to measure and record all specified KPIs.
 Continue the test until all traffic profile phases are completed.

 Within the test results validation criteria, the DUT/SUT is expected
 to reach the desired value of the target objective in the sustain
 phase.  Follow Step 3 if the measured value does not meet the target
 value or does not fulfill the test results validation criteria.

7.7.4.3. Step 3: Test Iteration

 Determine the achievable average inspected throughput within the test
 results validation criteria.  The final test iteration MUST be
 performed for the test duration defined in Section 4.3.4.

7.8. HTTPS Transaction Latency

7.8.1. Objective

 Using HTTPS traffic, determine the HTTPS transaction latency when the
 DUT/SUT is running with sustainable HTTPS transactions per second
 supported by the DUT/SUT under different HTTPS response object sizes.

 Scenario 1: The client MUST negotiate HTTPS and close the connection
 immediately after the completion of a single transaction (GET and
 RESPONSE).

 Scenario 2: The client MUST negotiate HTTPS and close the connection
 immediately after the completion of 10 transactions (GET and
 RESPONSE) within a single TCP or QUIC connection.

7.8.2. Test Setup

 The testbed setup MUST be configured as defined in Section 4.  Any
 specific testbed configuration changes (number of interfaces,
 interface type, etc.)  MUST be documented.

7.8.3. Test Parameters

 In this section, benchmarking-test-specific parameters are defined.

7.8.3.1. DUT/SUT Configuration Parameters

 DUT/SUT parameters MUST conform to the requirements defined in
 Section 4.2.  Any configuration changes for this specific
 benchmarking test MUST be documented.

7.8.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The following parameters MUST
 be documented for this benchmarking test:

• Client IP address ranges defined in Section 4.3.1.3

• Server IP address ranges defined in Section 4.3.2.3

• Traffic distribution ratio between IPv4 and IPv6 defined in

Section 4.3.1.3

• RECOMMENDED cipher suites and key sizes defined in Section 4.3.1.4

• Target objective for scenario 1: 50% of the connections per second

measured in the benchmarking test TCP or QUIC connections per

    second with HTTPS traffic (Section 7.6)

• Target objective for scenario 2: 50% of the inspected throughput

measured in the benchmarking test HTTPS throughput (Section 7.7)

• Initial objective for scenario 1: 10% of "Target objective for

scenario 1"

• Initial objective for scenario 2: 10% of "Target objective for

scenario 2"

    Note: The initial objectives are not KPIs to report.  These values
    are configured on the traffic generator and used to perform Step 1
    (Test Initialization and Qualification) described in
    Section 7.8.4.

• HTTPS transaction per TCP or QUIC connection: Test scenario 1 with

a single transaction and scenario 2 with 10 transactions

• HTTPS with GET request requesting a single object: The RECOMMENDED

object sizes are 1, 16, and 64 KB. For each test iteration, the

    client MUST request a single HTTPS response object size.

7.8.3.3. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 sustain phase of the traffic load profile.

 a.  The number of failed application transactions (receiving any HTTP
     response code other than 200 OK) MUST be less than 0.001% (1 out
     of 100,000 transactions) of the total attempted transactions.

 b.  The number of terminated TCP connections due to unexpected TCP
     RST sent by the DUT/SUT MUST be less than 0.001% (1 out of
     100,000 connections) of the total initiated TCP connections.  If
     HTTP/3 is used, the number of terminated QUIC connections due to
     unexpected errors MUST be less than 0.001% (1 out of 100,000
     connections) of the total initiated QUIC connections.

 c.  During the sustain phase, traffic MUST be forwarded at a constant
     rate (it is considered as a constant rate if any deviation of the
     traffic forwarding rate is less than 5%).

 d.  Concurrent TCP or QUIC connections MUST be constant during steady
     state, and any deviation of concurrent TCP connections MUST be
     less than 10%. If HTTP/3 is used, the concurrent generated QUIC
     connections MUST be constant during steady state, and any
     deviation of concurrent QUIC connections MUST be less than 10%.
     This confirms the DUT opens and closes connections at
     approximately the same rate.

 e.  After ramp up, the DUT/SUT MUST achieve the target objectives
     defined in the parameters in Section 7.8.3.2 and remain in that
     state for the entire test duration (sustain phase).

7.8.3.4. Measurement

 The TTFB (minimum, average, and maximum) and TTLB (minimum, average,
 and maximum) MUST be reported for each object size.

7.8.4. Test Procedures and Expected Results

 The test procedure is designed to measure the TTFB or TTLB when the
 DUT/SUT is operating close to 50% of its maximum achievable
 connections per second or inspected throughput.  The test procedure
 consists of two major steps.  Step 1 ensures the DUT/SUT is able to
 reach the initial performance values and meets the test results
 validation criteria when it is very minimally utilized.  Step 2
 measures the latency values within the test results validation
 criteria.

 This test procedure MAY be repeated multiple times with different IP
 types (IPv4 only, IPv6 only, and IPv4 and IPv6 mixed traffic
 distribution), HTTPS response object sizes, and single and multiple
 transactions per connection scenarios.

7.8.4.1. Step 1: Test Initialization and Qualification

 Verify the link status of all connected physical interfaces.  All
 interfaces are expected to be in "UP" status.

 Configure the traffic load profile of the test equipment to establish
 the initial objectives, as defined in Section 7.8.3.2.  The traffic
 load profile MUST be defined as described in Section 4.3.4.

 The DUT/SUT MUST reach the initial objectives before the sustain
 phase.  The measured KPIs during the sustain phase MUST meet all the
 test results validation criteria defined in Section 7.8.3.3.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT be continued to Step 2.

7.8.4.2. Step 2: Test Run with Target Objective

 Configure test equipment to establish the target objectives defined
 in Section 7.8.3.2.  The test equipment MUST follow the traffic load
 profile definition described in Section 4.3.4.

 The test equipment MUST start to measure and record all specified
 KPIs.  Continue the test until all traffic profile phases are
 completed.

 Within the test results validation criteria, the DUT/SUT MUST reach
 the desired value of the target objective in the sustain phase.

 Measure the minimum, average, and maximum values of the TTFB and
 TTLB.

7.9. Concurrent TCP or QUIC Connection Capacity with HTTPS Traffic

7.9.1. Objective

 Determine the number of concurrent TCP or QUIC connections the DUT/
 SUT sustains when using HTTPS traffic.

7.9.2. Test Setup

 The testbed setup MUST be configured as defined in Section 4.  Any
 specific testbed configuration changes (number of interfaces,
 interface type, etc.)  MUST be documented.

7.9.3. Test Parameters

 In this section, benchmarking-test-specific parameters are defined.

7.9.3.1. DUT/SUT Configuration Parameters

 DUT/SUT parameters MUST conform to the requirements defined in
 Section 4.2.  Any configuration changes for this specific
 benchmarking test MUST be documented.

7.9.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The following parameters MUST
 be documented for this benchmarking test:

• Client IP address ranges defined in Section 4.3.1.3

• Server IP address ranges defined in Section 4.3.2.3

• Traffic distribution ratio between IPv4 and IPv6 defined in

Section 4.3.1.3

• RECOMMENDED cipher suites and key sizes defined in Section 4.3.1.4

• Target concurrent connections: Initial value from the product

datasheet or the value defined based on the requirement for a

    specific deployment scenario

• Initial concurrent connections: 10% of "Target concurrent

connections"

    Note: Initial concurrent connections is not a KPI to report.  This
    value is configured on the traffic generator and used to perform
    Step 1 (Test Initialization and Qualification) described in
    Section 7.9.4.

• Connections per second during ramp up phase: 50% of maximum

connections per second measured in the benchmarking test TCP or

    QUIC connections per second with HTTPS traffic (Section 7.6)

• Ramp up time (in traffic load profile for "Target concurrent

connections"): "Target concurrent connections" / "Maximum

    connections per second during ramp up phase"

• Ramp up time (in traffic load profile for "Initial concurrent

connections"): "Initial concurrent connections" / "Maximum

    connections per second during ramp up phase"

 The client MUST perform HTTPS transactions with persistence, and each
 client can open multiple concurrent connections per server endpoint
 IP.

 Each client sends 10 GET requests requesting 1 KB HTTPS response
 objects in the same TCP or QUIC connections (10 transactions/
 connections), and the delay (think time) between each transaction
 MUST be X seconds, where X is as follows.

    X = ("Ramp up time" + "steady state time") / 10

 The established connections MUST remain open until the ramp down
 phase of the test.  During the ramp down phase, all connections MUST
 be successfully closed with FIN.

7.9.3.3. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 sustain phase of the traffic load profile.

 a.  The number of failed application transactions (receiving any HTTP
     response code other than 200 OK) MUST be less than 0.001% (1 out
     of 100,000 transactions) of the total attempted transactions.

 b.  The number of terminated TCP connections due to unexpected TCP
     RSTs sent by the DUT/SUT MUST be less than 0.001% (1 out of
     100,000 connections) of the total initiated TCP connections.  If
     HTTP/3 is used, the number of terminated QUIC connections due to
     unexpected errors MUST be less than 0.001% (1 out of 100,000
     connections) of the total initiated QUIC connections.

 c.  During the sustain phase, traffic MUST be forwarded at a constant
     rate (it is considered as a constant rate if any deviation of the
     traffic forwarding rate is less than 5%).

7.9.3.4. Measurement

 Average concurrent TCP or QUIC connections MUST be reported for this
 benchmarking test.

7.9.4. Test Procedures and Expected Results

 The test procedure is designed to measure the concurrent TCP
 connection capacity of the DUT/SUT at the sustaining period of the
 traffic load profile.  The test procedure consists of three major
 steps.  Step 1 ensures the DUT/SUT is able to reach the performance
 value (Initial concurrent connection) and meets the test results
 validation criteria when it was very minimally utilized.  Step 2
 determines whether the DUT/SUT is able to reach the target
 performance value within the test results validation criteria.  Step
 3 determines the maximum achievable performance value within the test
 results validation criteria.

 This test procedure MAY be repeated multiple times with different
 IPv4 and IPv6 traffic distributions.

7.9.4.1. Step 1: Test Initialization and Qualification

 Verify the link status of all connected physical interfaces.  All
 interfaces are expected to be in "UP" status.

 Configure test equipment to establish "Initial concurrent
 connections" defined in Section 7.9.3.2.  Except ramp up time, the
 traffic load profile MUST be defined as described in Section 4.3.4.

 During the sustain phase, the DUT/SUT MUST reach the "Initial
 concurrent connections".  The measured KPIs during the sustain phase
 MUST meet the test results validation criteria "a" and "b" defined in
 Section 7.9.3.3.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT be continued to Step 2.

7.9.4.2. Step 2: Test Run with Target Objective

 Configure test equipment to establish the target objective ("Target
 concurrent connections").  The test equipment MUST follow the traffic
 load profile definition (except ramp up time) described in
 Section 4.3.4.

 During the ramp up and sustain phases, the other KPIs, such as
 inspected throughput, TCP or QUIC connections per second, and
 application transactions per second, MUST NOT reach the maximum value
 that the DUT/SUT can support.

 The test equipment MUST start to measure and record KPIs defined in
 Section 7.9.3.4.  Continue the test until all traffic profile phases
 are completed.

 Within the test results validation criteria, the DUT/SUT is expected
 to reach the desired value of the target objective in the sustain
 phase.  Follow Step 3 if the measured value does not meet the target
 value or does not fulfill the test results validation criteria.

7.9.4.3. Step 3: Test Iteration

 Determine the achievable concurrent TCP or QUIC connections within
 the test results validation criteria.

8. IANA Considerations

 This document makes no specific request of IANA.

 IANA has assigned IPv4 and IPv6 address blocks in [RFC6890] that have
 been registered for special purposes.  The IPv6 address block
 2001:2::/48 has been allocated for the purpose of IPv6 benchmarking
 [RFC5180], and the IPv4 address block 198.18.0.0/15 has been
 allocated for the purpose of IPv4 benchmarking [RFC2544].  This
 assignment was made to minimize the chance of conflict in case a
 testing device were to be accidentally connected to the part of the
 Internet.

9. Security Considerations

 The primary goal of this document is to provide benchmarking
 terminology and methodology for next-generation network security
 devices for use in a laboratory-isolated test environment.  However,
 readers should be aware that there is some overlap between
 performance and security issues.  Specifically, the optimal
 configuration for network security device performance may not be the
 most secure, and vice versa.  Testing security platforms with working
 exploits and malware carries risks.  Ensure proper access controls
 are implemented to prevent unintended exposure to vulnerable networks
 or systems.  The cipher suites recommended in this document are for
 test purposes only.  The cipher suite recommendation for a real
 deployment is outside the scope of this document.

 Security assessment of an NGFW/NGIPS product could also include an
 analysis whether any type of uncommon traffic characteristics would
 have a significant impact on performance.  Such performance impacts
 would allow an attacker to use such specifically crafted traffic as a
 DoS attack to reduce the remaining performance available to other
 traffic through the NGFW/NGIPS.  Such uncommon traffic
 characteristics might include, for example, IP-fragmented traffic, a
 specific type of application traffic, or uncommonly high HTTP
 transaction rate traffic.

10. References

10.1. Normative References

 [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
            Requirement Levels", BCP 14, RFC 2119,
            DOI 10.17487/RFC2119, March 1997,
            <https://www.rfc-editor.org/info/rfc2119>.

 [RFC8174]  Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
            2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
            May 2017, <https://www.rfc-editor.org/info/rfc8174>.

10.2. Informative References

 [CVE]      CVE, "Current CVSS Score Distribution For All
            Vulnerabilities", <https://www.cvedetails.com/>.

 [fastly]   Oku, K. and J. Iyengar, "QUIC vs TCP: Which is Better?",
            April 2020, <https://www.fastly.com/blog/measuring-quic-
            vs-tcp-computational-efficiency>.

 [RFC2544]  Bradner, S. and J. McQuaid, "Benchmarking Methodology for
            Network Interconnect Devices", RFC 2544,
            DOI 10.17487/RFC2544, March 1999,
            <https://www.rfc-editor.org/info/rfc2544>.

 [RFC2647]  Newman, D., "Benchmarking Terminology for Firewall
            Performance", RFC 2647, DOI 10.17487/RFC2647, August 1999,
            <https://www.rfc-editor.org/info/rfc2647>.

 [RFC3511]  Hickman, B., Newman, D., Tadjudin, S., and T. Martin,
            "Benchmarking Methodology for Firewall Performance",
            RFC 3511, DOI 10.17487/RFC3511, April 2003,
            <https://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, <https://www.rfc-editor.org/info/rfc5180>.

 [RFC6815]  Bradner, S., Dubray, K., McQuaid, J., and A. Morton,
            "Applicability Statement for RFC 2544: Use on Production
            Networks Considered Harmful", RFC 6815,
            DOI 10.17487/RFC6815, November 2012,
            <https://www.rfc-editor.org/info/rfc6815>.

 [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,
            <https://www.rfc-editor.org/info/rfc6890>.

 [RFC8200]  Deering, S. and R. Hinden, "Internet Protocol, Version 6
            (IPv6) Specification", STD 86, RFC 8200,
            DOI 10.17487/RFC8200, July 2017,
            <https://www.rfc-editor.org/info/rfc8200>.

 [RFC8446]  Rescorla, E., "The Transport Layer Security (TLS) Protocol
            Version 1.3", RFC 8446, DOI 10.17487/RFC8446, August 2018,
            <https://www.rfc-editor.org/info/rfc8446>.

 [RFC9000]  Iyengar, J., Ed. and M. Thomson, Ed., "QUIC: A UDP-Based
            Multiplexed and Secure Transport", RFC 9000,
            DOI 10.17487/RFC9000, May 2021,
            <https://www.rfc-editor.org/info/rfc9000>.

 [RFC9001]  Thomson, M., Ed. and S. Turner, Ed., "Using TLS to Secure
            QUIC", RFC 9001, DOI 10.17487/RFC9001, May 2021,
            <https://www.rfc-editor.org/info/rfc9001>.

 [RFC9002]  Iyengar, J., Ed. and I. Swett, Ed., "QUIC Loss Detection
            and Congestion Control", RFC 9002, DOI 10.17487/RFC9002,
            May 2021, <https://www.rfc-editor.org/info/rfc9002>.

 [RFC9113]  Thomson, M., Ed. and C. Benfield, Ed., "HTTP/2", RFC 9113,
            DOI 10.17487/RFC9113, June 2022,
            <https://www.rfc-editor.org/info/rfc9113>.

 [RFC9114]  Bishop, M., Ed., "HTTP/3", RFC 9114, DOI 10.17487/RFC9114,
            June 2022, <https://www.rfc-editor.org/info/rfc9114>.

 [RFC9204]  Krasic, C., Bishop, M., and A. Frindell, Ed., "QPACK:
            Field Compression for HTTP/3", RFC 9204,
            DOI 10.17487/RFC9204, June 2022,
            <https://www.rfc-editor.org/info/rfc9204>.

 [RFC9293]  Eddy, W., Ed., "Transmission Control Protocol (TCP)",
            STD 7, RFC 9293, DOI 10.17487/RFC9293, August 2022,
            <https://www.rfc-editor.org/info/rfc9293>.

 [Undertow] undertow, "An in depth overview of HTTP/2",
            <https://undertow.io/blog/2015/04/27/An-in-depth-overview-
            of-HTTP2.html>.

 [Wiki-NGFW]
            Wikipedia, "Next-generation firewall", January 2023,
            <https://en.wikipedia.org/w/index.php?title=Next-
            generation_firewall&oldid=1133673904>.

Appendix A. Test Methodology - Security Effectiveness Evaluation

A.1. Test Objective

 This test methodology verifies the DUT/SUT is able to detect,
 prevent, and report the vulnerabilities.

 In this test, background test traffic will be generated to utilize
 the DUT/SUT.  In parallel, some malicious traffic will be sent to the
 DUT/SUT as encrypted and cleartext payload formats using a traffic
 generator.  Section 4.2.1 defines the selection of the malicious
 traffic from the Common Vulnerabilities and Exposures (CVEs) list for
 testing.

 The following KPIs are measured in this test:

• Number of blocked CVEs

• Number of bypassed (non-blocked) CVEs

• Background traffic performance (verify if the background traffic

is impacted while sending CVEs toward the DUT/SUT)

• Accuracy of DUT/SUT statistics in terms of vulnerabilities

reporting

A.2. Testbed Setup

 The same testbed MUST be used for security effectiveness tests and
 for benchmarking test cases defined in Section 7.

A.3. Test Parameters

 In this section, the benchmarking-test-specific parameters are
 defined.

A.3.1. DUT/SUT Configuration Parameters

 DUT/SUT configuration parameters MUST conform to the requirements
 defined in Section 4.2.  The same DUT configuration MUST be used for
 the security effectiveness test and for benchmarking test cases
 defined in Section 7.  The DUT/SUT MUST be configured in "Inline"
 mode, all detected attack traffic MUST be dropped, and the session
 MUST be reset

A.3.2. Test Equipment Configuration Parameters

 Test equipment configuration parameters MUST conform to the
 requirements defined in Section 4.3.  The same client and server IP
 ranges MUST be configured as used in the benchmarking test cases.  In
 addition, the following parameters MUST be documented for this
 benchmarking test:

• Background Traffic: 45% of maximum HTTP throughput and 45% of

maximum HTTPS throughput supported by the DUT/SUT (measured with

    object size 64 KB in the benchmarking tests HTTP(S) Throughput
    defined in Sections 7.3 and 7.7)

• RECOMMENDED CVE traffic transmission Rate: 10 CVEs per second

• It is RECOMMENDED to generate each CVE multiple times

(sequentially) at 10 CVEs per second.

• Ciphers and keys for the encrypted CVE traffic MUST use the same

cipher configured for HTTPS-traffic-related benchmarking tests

    (Sections 7.6-7.9)

A.4. Test Results Validation Criteria

 The following criteria are the test results validation criteria.  The
 test results validation criteria MUST be monitored during the whole
 test duration.

 a.  The number of failed application transactions in the background
     traffic MUST be less than 0.01% of the attempted transactions.

 b.  The number of terminated TCP or QUIC connections of the
     background traffic (due to unexpected errors) MUST be less than
     0.01% of the total initiated TCP connections in the background
     traffic.

 c.  During the sustain phase, traffic MUST be forwarded at a constant
     rate (it is considered as a constant rate if any deviation of the
     traffic forwarding rate is less than 5%).

 d.  A false positive MUST NOT occur in the background traffic.

A.5. Measurement

 The following KPI metrics MUST be reported for this test scenario:

 Mandatory KPIs:

• Blocked CVEs: They MUST be represented in the following ways:

1. Number of blocked CVEs out of total CVEs

1. Percentage of blocked CVEs

• Unblocked CVEs: They MUST be represented in the following ways:

1. Number of unblocked CVEs out of total CVEs

1. Percentage of unblocked CVEs

• Background traffic behavior: It MUST be represented in one of the

followings ways:

1. No impact: Considered as "no impact" if any deviation of the

traffic forwarding rate is less than or equal to 5% (constant

       rate)

1. Minor impact: Considered as "minor impact" if any deviation of

the traffic forwarding rate is greater than 5% and less than or

       equal to 10% (i.e., small spikes)

1. Heavy impact: Considered as "heavy impact" if any deviation of

the traffic forwarding rate is greater than 10% (i.e., large

       spikes) or reduced the background HTTP(S) throughput greater
       than 10%

• DUT/SUT reporting accuracy: The DUT/SUT MUST report all detected

vulnerabilities.

 Optional KPIs:

• List of unblocked CVEs

A.6. Test Procedures and Expected Results

 The test procedure is designed to measure the security effectiveness
 of the DUT/SUT at the sustaining period of the traffic load profile.
 The test procedure consists of two major steps.  This test procedure
 MAY be repeated multiple times with different IPv4 and IPv6 traffic
 distributions.

A.6.1. Step 1: Background Traffic

 Generate background traffic at the transmission rate defined in
 Appendix A.3.2.

 The DUT/SUT MUST reach the target objective (HTTP(S) throughput) in
 the sustain phase.  The measured KPIs during the sustain phase MUST
 meet all the test results validation criteria defined in
 Appendix A.4.

 If the KPI metrics do not meet the test results validation criteria,
 the test procedure MUST NOT be continued to Step 2.

A.6.2. Step 2: CVE Emulation

 While generating background traffic (in the sustain phase), send the
 CVE traffic, as defined in the parameter section (Appendix A.3.2).

 The test equipment MUST start to measure and record all specified
 KPIs.  Continue the test until all CVEs are sent.

 The measured KPIs MUST meet all the test results validation criteria
 defined in Appendix A.4.

 In addition, the DUT/SUT should report the detected vulnerabilities
 in the log correctly, or there MUST be reference material available
 that will allow for verification that the correct vulnerability was
 detected if, for example, a different naming convention is used.
 This reference material MUST be cited in the report.

Appendix B. DUT/SUT Classification

 This document aims to classify the DUT/SUT into four different
 categories based on its maximum-supported firewall throughput
 performance number defined in the vendor datasheet.  This
 classification MAY help users to determine specific configuration
 scales (e.g., number of ACL entries), traffic profiles, and attack
 traffic profiles, scaling those proportionally to the DUT/SUT sizing
 category.

 The four different categories are Extra Small (XS), Small (S), Medium
 (M), and Large (L).  The RECOMMENDED throughput values for the
 following categories are:

 Extra Small (XS) -  Supported throughput less than or equal to 1
    Gbit/s

 Small (S) -  Supported throughput greater than 1 Gbit/s and less than
    or equal to 5Gbit/s

 Medium (M) -  Supported throughput greater than 5 Gbit/s and less
    than or equal to 10Gbit/s

 Large (L) -  Supported throughput greater than 10 Gbit/s

Acknowledgements

 The authors wish to acknowledge the members of NetSecOPEN for their
 participation in the creation of this document.  Additionally, the
 following members need to be acknowledged:

 Anand Vijayan, Chris Marshall, Jay Lindenauer, Michael Shannon, Mike
 Deichman, Ryan Riese, and Toulnay Orkun.

Contributors

 The following individuals contributed significantly to the creation
 of this document:

 Alex Samonte, Amritam Putatunda, Aria Eslambolchizadeh, Chao Guo,
 Chris Brown, Cory Ford, David DeSanto, Jurrie Van Den Breekel,
 Michelle Rhines, Mike Jack, Ryan Liles, Samaresh Nair, Stephen
 Goudreault, Tim Carlin, and Tim Otto.

Authors' Addresses

 Balamuhunthan Balarajah
 Berlin
 Germany
 Email: bm.balarajah@gmail.com

 Carsten Rossenhoevel
 EANTC AG
 Salzufer 14
 10587 Berlin
 Germany
 Email: cross@eantc.de

 Brian Monkman
 NetSecOPEN
 417 Independence Court
 Mechanicsburg, PA 17050
 United States of America
 Email: bmonkman@netsecopen.org