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Cisco Catalyst 9200L and 9400 Series Switches running IOS-XE 16.9 Common Criteria Security Target Version 1.0 11 June 2019 Cisco Catalyst 9200L and 9400 Series Switches Page 2 of 67 Table of Contents 1 SECURITY TARGET INTRODUCTION .............................................................................8 1.1 ST and TOE Reference .................................................................................................... 8 1.2 TOE Overview ................................................................................................................. 8 1.2.1 TOE Product Type .................................................................................................... 9 1.2.2 Supported non-TOE Hardware/ Software/ Firmware............................................... 9 1.3 TOE DESCRIPTION....................................................................................................... 9 1.4 TOE Evaluated Configuration........................................................................................ 12 1.5 Physical Scope of the TOE............................................................................................. 12 1.6 Logical Scope of the TOE.............................................................................................. 15 1.6.1 Security Audit......................................................................................................... 15 1.6.2 Cryptographic Support............................................................................................ 16 1.6.3 Identification and authentication............................................................................. 18 1.6.4 Security Management ............................................................................................. 19 1.6.5 Protection of the TSF.............................................................................................. 19 1.6.6 TOE Access ............................................................................................................ 20 1.6.7 Trusted path/Channels ............................................................................................ 20 1.7 Excluded Functionality .................................................................................................. 20 2 Conformance Claims.............................................................................................................21 2.1 Common Criteria Conformance Claim .......................................................................... 21 2.2 Protection Profile Conformance..................................................................................... 21 2.2.1 Protection Profile Additions ................................................................................... 26 2.3 Protection Profile Conformance Claim Rationale.......................................................... 26 2.3.1 TOE Appropriateness.............................................................................................. 26 2.3.2 TOE Security Problem Definition Consistency...................................................... 26 2.3.3 Statement of Security Requirements Consistency.................................................. 26 3 SECURITY PROBLEM DEFINITION................................................................................28 3.1 Assumptions................................................................................................................... 28 3.2 Threats............................................................................................................................ 29 3.3 Organizational Security Policies.................................................................................... 30 4 SECURITY OBJECTIVES...................................................................................................31 4.1 Security Objectives for the TOE .................................................................................... 31 4.2 Security Objectives for the Environment....................................................................... 31 5 SECURITY REQUIREMENTS ...........................................................................................32 5.1 Conventions.................................................................................................................... 32 5.2 TOE Security Functional Requirements ........................................................................ 32 5.2.1 Security audit (FAU)............................................................................................... 33 5.2.2 Cryptographic Support (FCS)................................................................................. 35 5.2.3 Identification and authentication (FIA) .................................................................. 40 5.2.4 Security management (FMT).................................................................................. 42 5.2.5 Protection of the TSF (FPT) ................................................................................... 43 5.2.6 TOE Access (FTA) ................................................................................................. 44 5.2.7 Trusted Path/Channels (FTP).................................................................................. 44 5.3 TOE SFR Dependencies Rationale for SFRs Found in NDcPPv2.0.............................. 45 Cisco Catalyst 9200L and 9400 Series Switches Page 3 of 67 5.4 Security Assurance Requirements.................................................................................. 45 5.4.1 SAR Requirements.................................................................................................. 45 5.4.2 Security Assurance Requirements Rationale.......................................................... 46 5.5 Assurance Measures....................................................................................................... 46 6 TOE Summary Specification ................................................................................................48 6.1 TOE Security Functional Requirement Measures.......................................................... 48 7 Annex A: Key Zeroization....................................................................................................64 7.1 Key Zeroization.............................................................................................................. 64 8 Annex B: References.............................................................................................................67 Cisco Catalyst 9200L and 9400 Series Switches Page 4 of 67 List of Tables TABLE 1 ACRONYMS............................................................................................................................................................................................ 5 TABLE 2 TERMINOLOGY ..................................................................................................................................................................................... 6 TABLE 3 ST AND TOE IDENTIFICATION.......................................................................................................................................................... 8 TABLE 4 IT ENVIRONMENT COMPONENTS...................................................................................................................................................... 9 TABLE 5 HARDWARE MODELS AND SPECIFICATIONS .................................................................................................................................13 TABLE 6 FIPS REFERENCES.............................................................................................................................................................................16 TABLE 7 TOE PROVIDED CRYPTOGRAPHY ...................................................................................................................................................17 TABLE 8 CATALYST 9200L AND 9400 SERIES SWITCH PLATFORM PROCESSORS................................................................................18 TABLE 9 EXCLUDED FUNCTIONALITY ............................................................................................................................................................20 TABLE 10 NIAP TECHNICAL DECISIONS (TD).............................................................................................................................................21 TABLE 11 PROTECTION PROFILES ..................................................................................................................................................................26 TABLE 12 TOE ASSUMPTIONS ........................................................................................................................................................................28 TABLE 13 THREATS..........................................................................................................................................................................................29 TABLE 14 ORGANIZATIONAL SECURITY POLICIES.......................................................................................................................................30 TABLE 15 SECURITY OBJECTIVES FOR THE ENVIRONMENT........................................................................................................................31 TABLE 16 SECURITY FUNCTIONAL REQUIREMENTS....................................................................................................................................32 TABLE 17 AUDITABLE EVENTS.......................................................................................................................................................................34 TABLE 18: ASSURANCE MEASURES.................................................................................................................................................................46 TABLE 19 ASSURANCE MEASURES..................................................................................................................................................................46 TABLE 20 HOW TOE SFRS MEASURES.........................................................................................................................................................48 TABLE 21: TOE KEY ZEROIZATION................................................................................................................................................................64 TABLE 22: REFERENCES ...................................................................................................................................................................................67 List of Figures FIGURE 1 TOE EXAMPLE DEPLOYMENT .......................................................................................................................................................11 Cisco Catalyst 9200L and 9400 Series Switches Page 5 of 67 Acronyms The following acronyms and abbreviations are common and may be used in this Security Target: Table 1 Acronyms Acronyms / Abbreviations Definition AAA Administration, Authorization, and Accounting ACL Access Control Lists AES Advanced Encryption Standard BRI Basic Rate Interface CC Common Criteria for Information Technology Security Evaluation CEM Common Evaluation Methodology for Information Technology Security CM Configuration Management CSU Channel Service Unit DHCP Dynamic Host Configuration Protocol DSU Data Service Unit EAL Evaluation Assurance Level EHWIC Ethernet High-Speed WIC ESP Encapsulating Security Payload GE Gigabit Ethernet port HTTP Hyper-Text Transport Protocol HTTPS Hyper-Text Transport Protocol Secure ICMP Internet Control Message Protocol ISDN Integrated Services Digital Network IT Information Technology NDcPP collaborative Protection Profile for Network Devices OS Operating System PBKDF2 Password-Based Key Derivation Function version 2 PoE Power over Ethernet POP3 Post Office Protocol PP Protection Profile SA Security Association SFP Small–form-factor pluggable port SHS Secure Hash Standard SIP Session Initiation Protocol SSHv2 Secure Shell (version 2) ST Security Target TCP Transport Control Protocol TOE Target of Evaluation TSC TSF Scope of Control TSF TOE Security Function TSP TOE Security Policy UDP User datagram protocol WAN Wide Area Network WIC WAN Interface Card Terminology The following terms are common and may be used in this Security Target: Cisco Catalyst 9200L and 9400 Series Switches Page 6 of 67 Table 2 Terminology Term Definition Authorized Administrator Any user which has been assigned to a privilege level that is permitted to perform all TSF- related functions. Peer Another switch on the network that the TOE interfaces. Remote TOE Peer A remote TOE Peer is another network device that the TOE sets up a VPN connection with. Security Administrator Synonymous with Authorized Administrator for the purposes of this evaluation. User Any entity (human user or external IT entity) outside the TOE that interacts with the TOE. vty vty is a term used by Cisco to describe a single terminal (whereas Terminal is more of a verb or general action term). Firmware (per NIST for FIPS validated cryptographic modules) The programs and data components of a cryptographic module that are stored in hardware (e.g., ROM, PROM, EPROM, EEPROM or FLASH) within the cryptographic boundary and cannot be dynamically written or modified during execution. Cisco Catalyst 9200L and 9400 Series Switches Page 7 of 67 DOCUMENT INTRODUCTION Prepared By: Cisco Systems, Inc. 170 West Tasman Dr. San Jose, CA 95134 This document provides the basis for an evaluation of a specific Target of Evaluation (TOE), the Cisco Catalyst 9200L and 9400 Series Switches (Cat 9K Series) running IOS-XE 16.9. This Security Target (ST) defines a set of assumptions about the aspects of the environment, a list of threats that the product intends to counter, a set of security objectives, a set of security requirements, and the IT security functions provided by the TOE, which meet the set of requirements. Administrators of the TOE may be referred to as administrators, Authorized Administrators, TOE administrators, semi-privileged, privileged administrators, and security administrators in this document. Cisco Catalyst 9200L and 9400 Series Switches Page 8 of 67 1 SECURITY TARGET INTRODUCTION The Security Target contains the following sections: • Security Target Introduction [Section 1] • Conformance Claims [Section 2] • Security Problem Definition [Section 3] • Security Objectives [Section 4] • IT Security Requirements [Section 5] • TOE Summary Specification [Section 6] The structure and content of this ST comply with the requirements specified in the Common Criteria (CC), Part 1, Annex A, and Part 2. 1.1 ST and TOE Reference This section provides information needed to identify and control this ST and its TOE. Table 3 ST and TOE Identification Name Description ST Title Cisco Catalyst 9200L and 9400 Series Switches running IOS-XE 16.9 ST Version 1.0 Publication Date 11 June 2019 Vendor and ST Author Cisco Systems, Inc. TOE Reference Cisco Catalyst 9200L and 9400 Series Switches TOE Hardware Models 9200L and 9400 Series TOE Software Version IOS-XE 16.9 Keywords Audit, Authentication, Encryption, Network Device, Secure Administration 1.2 TOE Overview The Cisco Catalyst 9200L and 9400 Series Switches running IOS-XE 16.9 (herein after referred to as Cisco Cat 9K Series). The TOE is a purpose-built, switching and routing platform with OSI Layer2 and Layer3 traffic filtering capabilities. The TOE is a switching and routing platform used to construct IP networks by interconnecting multiple smaller networks or network segments. As a Layer2 switch, it performs analysis of incoming frames, makes forwarding decisions based on information contained in the frames, and forwards the frames toward the destination. As a Layer3 switch/router, it supports routing of traffic based on tables identifying available routes, conditions, distance, and costs to determine the best route for a given packet. The TOE includes the hardware models as defined in Table 3 in Section 1.1. Cisco IOS-XE software is a Cisco-developed highly configurable proprietary operating system that provides for efficient and effective switching and routing. Although IOS-XE performs many networking functions, this Security Target only addresses the functions that provide for the security of the TOE itself as described in Section 1.7 TOE logical scope below. Cisco Catalyst 9200L and 9400 Series Switches Page 9 of 67 1.2.1 TOE Product Type The Cisco Cat 9K Series are switching and routing platforms that provide connectivity and security services onto a single, secure device. These switches are capable of delivering from 2 to 11 terabits per second of bandwidth capacity and from 56 Gbps up to 440 Gbps of per-slot bandwidth. The Cat 9K Series switches also provides simplified management suited for enterprise core and aggregation environments. The Cisco Cat 9K Series switches are single-device security and switching solutions for protecting the network. 1.2.2 Supported non-TOE Hardware/ Software/ Firmware The TOE supports the following hardware, software, and firmware components in its operational environment. Each component is identified as being required or not based on the claims made in this Security Target. All of the following environment components are supported by all TOE evaluated configurations: Table 4 IT Environment Components Component Required Usage/Purpose Description for TOE performance Audit (syslog) Server Yes This includes any syslog server to which the TOE transmits syslog messages over a secure IPsec trusted channel either directly or connected to a TOE Peer that also supports a secure IPsec trusted channel Local Console Yes This includes any IT Environment Console that is directly connected to the TOE via the Serial Console Port and is used by the TOE administrator to support TOE administration. Management Workstation with SSHv2 client Yes This includes any IT Environment Management workstation that is used by the TOE administrator to support TOE administration using SSHv2 protected channels. Any SSH client that supports SSHv2 may be used. RADIUS Authentication (AAA) Server Yes This includes any IT environment RADIUS AAA server that provides authentication services to TOE administrators over a secure IPsec trusted channel either directly or connected to a TOE Peer that also supports a secure IPsec trusted channel. Certification Authority (CA) Yes This includes any IT Environment Certification Authority (CA) on the TOE network. The CA can be used to provide the TOE with a valid certificate during certificate enrollment as well as validating a certificate. TOE Peer Yes The TOE Peer is required if the remote syslog server and/or the remote authentication is attached for the TOE’s use. 1.3 TOE DESCRIPTION This section provides an overview of the Cisco Catalyst 9200L and 9400 Series Switches Target of Evaluation (TOE). The TOE is comprised of both software and hardware. The hardware is comprised of the 9200L and 9400 Series Switches. The software is comprised of the Universal Cisco Internet Operating System (IOS) software image Release IOS-XE 16.9. Cisco Catalyst 9200L and 9400 Series Switches Page 10 of 67 The Catalyst 9200L and 9400 Series Switches that comprises the TOE have common hardware characteristics. These characteristics affect only non-TSF relevant functions of the switches (such as throughput and amount of storage) and therefore support security equivalency of the switches in terms of hardware. The Catalyst 9200L and 9400 Series Switches features include the following: • Central processor that supports all system operations; • Dynamic memory, used by the central processor for all system operation; • Flash memory (EEPROM), used to store the Cisco IOS image (binary program); • USB port (v2.0) (note, none of the USB devices are included in the TOE); o Type A for Storage, all Cisco supported USB flash drives; • Non-volatile read-only memory (ROM) is used to store the bootstrap program and power- on diagnostic programs; • Non-volatile random-access memory (NVRAM) is used to store switch configuration parameters that are used to initialize the system at start-up; and • Physical network interfaces (minimally two) (e.g. RJ45 serial and standard 10/100/1000 Ethernet ports for direct local console access for administration). Some models have a fixed number and/or type of interfaces; some models have slots that accept additional network interfaces. Cisco IOS-XE software is a Cisco-developed highly configurable proprietary operating system that provides for efficient and effective routing and switching. Although IOS-XE performs many networking functions, this TOE only addresses the functions that provide for the security of the TOE itself as described in Section 1.6 Logical Scope of the TOE below. The following figure provides a visual depiction of an example TOE deployment. The TOE boundary is surrounded with a hashed red line. Cisco Catalyst 9200L and 9400 Series Switches Page 11 of 67 Figure 1 TOE Example Deployment The previous figure includes the following devices, noting the TOE is only the Catalyst 9200L and 9400 Series Switches and only one TOE device is required for the deployment of the TOE in the evaluated configuration: • The TOE models: o Catalyst 9200L and 9400 Series • The following are considered to be in the IT Environment: o Audit (syslog) Server o Local Console, directly connected to the TOE for administration Management Workstation Network 1 Syslog Server AAA Server TOE Models and Software Version as listed below in Table 3 IPsec connection SSH connection Local Console Direct connection Network 2 TOE Peer IPsec connection Certificate Authority (CA) Cisco Catalyst 9200L and 9400 Series Switches Page 12 of 67 o Management Workstation with SSHv2 Client o RADIUS Authentication (AAA) Server o Certificate Authority (CA) o TOE Peer 1.4 TOE Evaluated Configuration The TOE consists of one or more physical devices as described below and includes the Cisco IOS- XE 16.9 software. The TOE has two or more network interfaces and is connected to at least one internal and one external network. The Cisco IOS-XE configuration determines how packets are handled to and from the TOE’s network interfaces. The switch configuration will determine how traffic flows received on an interface will be handled. Typically, packet flows are passed through the internetworking device and forwarded to their configured destination. In addition, if the Catalyst 9200L and 9400 Series Switches is to be remotely administered, then the management workstation must be connected to an internal network, SSHv2 is used to securely connect to the switch. A syslog server is used to store audit records, where IPsec is used to secure the transmission of the records. If these servers are used, they must be attached to the internal (trusted) network. The internal (trusted) network is meant to be separated effectively from unauthorized individuals and user traffic; one that is in a controlled environment where implementation of security policies can be enforced. 1.5 Physical Scope of the TOE The TOE is a hardware and software solution that makes up the switch models as follows: the Catalyst 9200L and 9400 Series running Cisco IOS-XE 16.9. The switch chassis provides power, cooling and backplane for the Network Module, Supervisor Engine, line cards and service modules. The network, on which they reside, is considered part of the environment. The TOE guidance documentation that is considered to be part of the TOE can be found listed in the Cisco Catalyst 9200L and 9400 Series Switches Common Criteria Operational User Guidance and Preparative Procedures document and are downloadable from the http://cisco.com web site. The TOE is comprised of the following physical specifications as described in Table 5 Hardware Models and Specifications below: Cisco Catalyst 9200L and 9400 Series Switches Page 13 of 67 Table 5 Hardware Models and Specifications Hardware Processor Software Picture Size Power Interfaces Cisco Catalyst 9200L Series is made up of the following models: C9200L- 24P-4G C9200L- 24P-4X C9200L- 24T-4G C9200L- 24T-4X C9200L- 48P-4G C9200L- 48P-4X C9200L- 48T-4G C9200L- 48T-4X ARM A53 Cisco IOS-XE 16.9 1.73 x 17.5 x 15.4 in and 9.59lbs Catalyst 9200L Series switches support dual field- replaceable power supplies. Each switch ships with one default power supply and a second identical power supply can be purchased with the initial order or can be added later. The second power supply can provide redundancy or additional power to PoE+ ports as needed ● 1000BASE-T ports: RJ-45 connectors, 4-pair Cat 5E UTP cabling ● 1000BASE-T SFP- based ports: RJ-45 connectors, 4-pair Cat 5E UTP cabling ● 100BASE-FX, 1000BASE-SX, - LX/LH, -ZX, -BX10, dense wavelength- division multiplexing (DWDM) and Coarse Wavelength-Division Multiplexing (CWDM) SFP transceivers: LC fiber connectors (single- mode or multimode fiber) ● SFP+ connector ● Cisco StackWise- 160/80 stacking ports: copper-based Cisco StackWise cabling ● Ethernet management port: RJ- 45 connectors, 4-pair Cat 5 UTP cabling ● Management console port: RJ-45- to-DB9 cable for PC connections, USB-C adaptor, USB adaptor Cisco Catalyst 9200L and 9400 Series Switches Page 14 of 67 Cisco Catalyst 9400 Series is made up of the following models: C9404R C9407R C9410R Intel Xeon D Cisco IOS-XE 16.9 C9404R is a 6RU – 10.47 x 17.30 x 16.30 in And 39.0lb C9407R is a 10RU - 17.41 x 17.30 x 16.30 in and 63.0 lb. C9410R is a13 RU - 22.61 x 17.30 x 16.30 in and 65.0 lb There are three modes of operation supported by Cisco Catalyst 9400 power supplies. In all the modes the power supplies can be of different wattage and type whether AC or DC. Redundant N + N mode The Cisco Catalyst 9400 Chassis also supports N + N redundancy with N independent input circuits and safeguards against failure of N (+N) of the circuits as opposed to power supply unit failure. Redundant N + 1 mode The Cisco Catalyst 9400 Chassis also supports N + 1 redundancy with N independent input circuits and safeguards against failure of one (+1) of the circuits as opposed to power supply unit failure. Combined mode In this mode the power available for All models support C9400-SUP-1, C9400-SUP-1XL and C9400-SUP-1XL-Y supervisor cards Linecards are not supported in the Supervisor slots Ethernet management port: RJ-45 connectors, 4-pair Cat 5 UTP cabling Management console port: RJ-45-to-DB9 cable for PC connections, USB-C adaptor, USB adaptor Cisco Catalyst 9200L and 9400 Series Switches Page 15 of 67 Hardware Processor Software Picture Size Power Interfaces the entire chassis is equal to the sum of the output power of both of the power supplies multiplied by the share ratio. P = Power output of one power-supply unit Total combined mode power = P + (N-1) * P * (share ratio) 1.6 Logical Scope of the TOE The TOE is comprised of several security features. Each of the security features identified above consists of several security functionalities, as identified below. • Security Audit • Cryptographic Support • Identification and Authentication • Security Management • Protection of the TSF • TOE Access • Trusted Path/Channels These features are described in more detail in the subsections below. In addition, the TOE implements all RFCs of the NDcPPv2.0e as necessary to satisfy testing/assurance measures prescribed therein. 1.6.1 Security Audit The Cisco Catalyst 9200L and 9400 Series Switches provide extensive auditing capabilities. The TOE generates a comprehensive set of audit logs that identify specific TOE operations. For each event, the TOE records the date and time of each event, the type of event, the subject identity that triggered the event and the outcome of the event. The auditable events include: • failure on invoking cryptographic functionality such as establishment, termination and failure of cryptographic session establishments and connections; Cisco Catalyst 9200L and 9400 Series Switches Page 16 of 67 • modifications to the group of users that are part of the authorized administrator roles; • all use of the user identification mechanism; • any use of the authentication mechanism; • Administrator lockout due to excessive authentication failures; • any change in the configuration of the TOE; • changes to time; • initiation of TOE update; • indication of completion of TSF self-test; • maximum sessions being exceeded; • termination of a remote session; • attempts to unlock a termination session and • initiation and termination of a trusted channel. The TOE is configured to transmit the audit messages to an external syslog server. Communication with the syslog server is protected by using IPsec and the TOE can determine when communication with the syslog server fails. If that should occur, the TOE can be configured to block new permit actions. The audit logs can be viewed on the TOE using the appropriate IOS commands. The records include the date/time the event occurred, the event/type of event, the user associated with the event, and additional information of the event and its success and/or failure. The TOE does not have an interface to modify audit records, though there is an interface available for the authorized administrator to clear (delete) audit data stored locally on the TOE. 1.6.2 Cryptographic Support The TOE provides cryptography in support of other TOE security functionality. All the algorithms claimed have CAVP certificates (Operation Environment – ARM A53 (9200L) and Intel Xeon D (9400) processor). The TOE leverages the IOS Common Cryptographic Module (IC2M) Rel5 as identified in the table below. The IOS software calls the IOS Common Cryptographic Module (IC2M) Rel5 (Firmware Version: Rel 5) for all cryptographic functions. Refer to Table 6 for algorithm certificate references. Table 6 FIPS References Algorithm Description Supported Mode CAVP Cert. # Module SFR AES Used for symmetric encryption/decryption AES Key Wrap in CBC (128 and 256 bits) C462 IC2M FCS_COP.1/DataEncryption SHS (SHA- 1, SHA-256 Cryptographic hashing services Byte Oriented C462 IC2M FCS_COP.1/Hash Cisco Catalyst 9200L and 9400 Series Switches Page 17 of 67 Algorithm Description Supported Mode CAVP Cert. # Module SFR and SHA- 512) HMAC (HMAC- SHA-1, HMAC- SHA-256 and HMAC- SHA-512) Keyed hashing services and software self-integrity test Byte Oriented C462 IC2M FCS_COP.1/KeyedHash DRBG Deterministic random bit generation services in accordance with ISO/IEC 18031:2011 CTR_DRBG (AES 256) C462 IC2M FCS_RBG_EXT.1 RSA Signature Verification and key transport FIPS PUB 186-4 Key Generation PKCS #1 v2.1 2048 bit key C462 IC2M FCS_CKM.1 FCS_COP.1/SigGen The TOE provides cryptography in support of VPN connections that includes remote administrative management via SSHv2 and IPsec to secure the transmission of audit records to the remote syslog server. In addition, IPsec is used to secure the session between the TOE and the authentication servers. The cryptographic services provided by the TOE are described in Table 7 below. Table 7 TOE Provided Cryptography Cryptographic Method Use within the TOE AES Used to encrypt IPsec session traffic. Used to encrypt SSH session traffic. HMAC Used for keyed hash, integrity services in IPsec and SSH session establishment. DH Used as the Key exchange method for IPsec and SSH Internet Key Exchange Used to establish initial IPsec session. RSA Used in IKE protocols peer authentication Used to provide cryptographic signature services Used in Cryptographic Key Generation RSA Signature Services Used in IPsec session establishment. Used in SSH session establishment. X.509 certificate signing. Secure Shell Establishment Used to establish initial SSH session. Cisco Catalyst 9200L and 9400 Series Switches Page 18 of 67 Cryptographic Method Use within the TOE SHS Used to provide IPsec traffic integrity verification Used to provide SSH traffic integrity verification Used for keyed-hash message authentication SP 800-90 RBG Used for random number generation, key generation and seeds to asymmetric key generation Used in IPsec session establishment. Used in SSH session establishment The Catalyst 9200L and 9400 Series Switches platforms contain the following processors as listed in Table 8 Catalyst 9200L and 9400 Series Switch Platform Processors Table 8 Catalyst 9200L and 9400 Series Switch Platform Processors Chassis CPU Designation 9200L ARM A53 9400 Intel Xeon D 1.6.3 Identification and authentication The TOE performs two types of authentication: device-level authentication of the remote device (VPN peers) and user authentication for the Authorized Administrator of the TOE. Device-level authentication allows the TOE to establish a secure channel with a trusted peer. The secure channel is established only after each device authenticates the other. Device-level authentication is performed via IKE/IPsec mutual authentication. The IKE phase authentication for the IPsec communication channel between the TOE and authentication server and between the TOE and syslog server is considered part of the Identification and Authentication security functionality of the TOE. The TOE provides authentication services for administrative users to connect to the TOEs secure CLI administrator interface. The TOE requires Authorized Administrators to authenticate prior to being granted access to any of the management functionality. The TOE can be configured to require a minimum password length of 15 characters as well as mandatory password complexity rules. The TOE provides administrator authentication against a local user database. Password- based authentication is performed on the directly connected local serial console and the remote console secure SSHv2 interfaces. The SSHv2 interface also supports authentication using SSH keys. The TOE supports use of a RADIUS AAA server (part of the IT Environment) for authentication of administrative users attempting to connect to the TOE’s CLI. The TOE also provides an automatic lockout when a user attempts to authenticate and enters invalid information. When the threshold for a defined number of authentication attempts fail has exceeded the configured allowable attempts, the user is locked out until an authorized administrator can enable the user account. Cisco Catalyst 9200L and 9400 Series Switches Page 19 of 67 The TOE uses X.509v3 certificates as defined by RFC 5280 to support authentication for IPsec connections. 1.6.4 Security Management The TOE provides secure administrative services for management of general TOE configuration and the security functionality provided by the TOE. All TOE administration occurs either through a remote secure SSHv2 session or via a direct local console connection. The TOE provides the following functionality to securely manage the TOE: • Administration of the TOE locally and remotely; • Configuration of warning and consent access banners; • Configuration of session inactivity thresholds; • Updates of the TOE software; • Configuration of authentication failures; • Configure lockout time interval for excessive authentication failures; • Configuration of the audit functions of the TOE; and • Configuration of the cryptographic functionality of the TOE. The TOE supports two separate administrator roles: non-privileged administrator and privileged administrator. Only the privileged administrator can perform the above security relevant management functions. The privileged administrator is the Authorized Administrator of the TOE who has the ability to enable, disable, determine and modify the behavior of all of the security functions of the TOE as described in this document. 1.6.5 Protection of the TSF The TOE protects against interference and tampering by untrusted subjects by implementing identification, authentication, and access controls to limit configuration to Authorized Administrators. The TOE prevents reading of cryptographic keys and passwords. Additionally, Cisco IOS-XE is not a general-purpose operating system and access to Cisco IOS-XE memory space is restricted to only Cisco IOS-XE functions. The TOE is able to verify any software updates prior to the software updates being installed on the TOE to avoid the installation of unauthorized software. The TOE internally maintains the date and time. This date and time is used as the timestamp that is applied to audit records generated by the TOE. The TOE provides the Authorized Administrators the capability to update the TOE’s clock manually to maintain a reliable timestamp. Finally, the TOE performs testing to verify correct operation of the TOE itself and that of the cryptographic module. Cisco Catalyst 9200L and 9400 Series Switches Page 20 of 67 1.6.6 TOE Access The TOE can terminate inactive sessions after an Authorized Administrator configurable time- period. Once a session has been terminated, the TOE requires the user to re-authenticate to establish a new session. The TOE can also display an Authorized Administrator specified banner on the CLI management interface prior to allowing any administrative access to the TOE. 1.6.7 Trusted path/Channels The TOE allows trusted paths to be established to itself from remote administrators over SSHv2 and initiates outbound IPsec tunnels to transmit audit messages to remote syslog servers. In addition, IPsec is used to secure the session between the TOE and the remote authentication servers. The TOE can also establish trusted paths of peer-to-peer IPsec sessions. The peer-to-peer IPsec sessions can be used for securing the communications between the TOE and authentication server/syslog server. 1.7 Excluded Functionality The following functionality is excluded from the evaluation. Table 9 Excluded Functionality Excluded Functionality Exclusion Rationale Non-FIPS 140-2 mode of operation This mode of operation includes non-FIPS allowed operations. This service can be disabled by configuration settings as described in the Guidance documents (AGD). The exclusion of this functionality does not affect the compliance to the collaborative Protection Profile for Network Devices Version 2.0 + Errata 20180314. Cisco Catalyst 9200L and 9400 Series Switches Page 21 of 67 2 CONFORMANCE CLAIMS 2.1 Common Criteria Conformance Claim The TOE and ST are compliant with the Common Criteria (CC) Version 3.1, Revision 4, dated: September 2012. For a listing of Assurance Requirements claimed, see section 5.4. The TOE and ST are CC Part 2 extended and CC Part 3 conformant. 2.2 Protection Profile Conformance The TOE and ST are conformant with the Protection Profiles as listed in Table 11 Protection Profiles below. The following NIAP Technical Decisions (TD) have also been applied to the claims in this document. Each posted TD was reviewed and considered based on the TOE product type, the PP claims and the security functional requirements claimed in this document. Table 10 NIAP Technical Decisions (TD) TD Identifier TD Name Protection Profiles References Publication Date Applicable? TD0412 NIT Technical Decision for FCS_SSHS_E XT.1.5 SFR and AA discrepancy CPP_FW_V2.0E, CPP_ND_V2.0, CPP_ND_V2.1 FCS_SSHS_EXT.1.5, ND SD V2.0e, ND SD V2.1 2019.03.22 Yes - TD has been applied TD0411 NIT Technical Decision for FCS_SSHC_E XT.1.5, Test 1 - Server and client side seem to be confused CPP_FW_V2.0E, CPP_ND_V2.0E, CPP_ND_V2.1 FCS_SSHC_EXT.1.5, ND SD V2.0E, ND SD V2.1 2019.03.22 Yes - TD has been applied TD0410 NIT technical decision for Redundant assurance activities associated with FAU_GEN.1 CPP_ND_V1.0, CPP_ND_V2.0E, CPP_ND_V2.1 FAU_GEN.1, ND SD V1.0, ND SD V2.0e, ND SD V2.1 2019.03.22 Yes - TD has been applied TD0409 NIT decision for Applicability of FIA_AFL.1 to key-based SSH authentication CPP_ND_V2.0E, CPP_ND_V2.1 FIA_AFL.1, ND SD v2.0e, ND SD v2.1 2019.03.22 No, referenced features is not being claimed TD0408 NIT Technical Decision for local vs. remote CPP_FW_V2.0E, CPP_ND_V2.0E, CPP_ND_V2.1 FIA_AFL.1, FIA_UAU_EXT.2, FMT_SMF.1 2019.03.22 Yes - TD has been applied Cisco Catalyst 9200L and 9400 Series Switches Page 22 of 67 TD Identifier TD Name Protection Profiles References Publication Date Applicable? administrator accounts TD0407 NIT Technical Decision for handling Certification of Cloud Deployments CPP_ND_V2.0E, CPP_ND_V2.1 2019.03.22 No, referenced features is not being claimed TD0402 NIT Technical Decision for RSA-based FCS_CKM.2 Selection CPP_FW_V2.0E, CPP_ND_V2.0E FCS_CKM.2, ND SD V2.0E 2019.02.24 Yes - TD has been applied TD0401 NIT Technical Decision for Reliance on external servers to meet SFRs CPP_ND_V2.0E FTP_ITC.1 2019.02.24 Yes - TD has been applied TD0400 NIT Technical Decision for FCS_CKM.2 and elliptic curve-based key establishment CPP_FW_V2.0E, CPP_ND_V2.0E FCS_CKM.1, FCS_CKM.2 2019.02.24 No, referenced algorithm is not being claimed TD0399 NIT Technical Decision for Manual installation of CRL (FIA_X509_E XT.2) CPP_ND_V2.0E, CPP_ND_V2.1 FIA_X509_EXT.2, ND SD V2.0E, ND SD V2.1 2019.02.24 Yes - TD has been applied TD0398 NIT Technical Decision for FCS_SSH*EX T.1.1 RFCs for AES-CTR CPP_FW_V2.0E, CPP_ND_V2.0E FCS_SSHC_EXT.1.1, FCS_SSHS_EXT.1.1, 2019.02.24 No, referenced algorithm is not being claimed TD0397 NIT Technical Decision for Fixing AES- CTR Mode Tests CPP_ND_V2.0E FCS_COP.1/DataEncrypt ion, ND SD V2.0E 2019.02.24 No, referenced algorithm is not being claimed TD0396 NIT Technical Decision for FCS_TLSC_E XT.1.1, Test 2 CPP_ND_V2.0E FCS_DTLSC_EXT.1.1, FCS_DTLSC_EXT.2.1, FCS_TLSC_EXT.1.1, FCS_TLSC_EXT.2.1, ND SD V2.0E 2019.02.24 No, Referenced SFR is not being claimed Cisco Catalyst 9200L and 9400 Series Switches Page 23 of 67 TD Identifier TD Name Protection Profiles References Publication Date Applicable? TD0395 NIT Technical Decision for Different Handling of TLS1.1 and TLS1.2 CPP_ND_V2.0E FCS_TLSS_EXT.2.4, FCS_TLSS_EXT.2.5, ND SD V2.0E 2019.02.24 No, Referenced SFR is not being claimed TD0394 NIT Technical Decision for Audit of Management Activities related to Cryptographic Keys CPP_FW_V2.0E, CPP_ND_V2.0E FAU_GEN.1, ND SD v2.0E 2019.02.24 Yes - TD has been applied TD0343 NIT Technical Decision for Updating FCS_IPSEC_E XT.1.14 Tests CPP_FW_V2.0E, CPP_ND_V2.0E ND SD V2.0, FCS_IPSEC_EXT.1.14 2018.08.02 Yes - TD has been applied TD0342 NIT Technical Decision for TLS and DTLS Server Tests CPP_ND_V2.0E ND SD V2.0, FCS_DTLSS_EXT.1, FCS_DTLSS_EXT.2, FCS_TLSS_EXT.1, FCS_TLSS_EXT.2 2018.08.02 No - Referenced SFR is not being claimed. TD0341 NIT Technical Decision for TLS wildcard checking CPP_ND_V2.0E ND SD V2.0, FCS_TLSC_EXT.1.2, FCS_TLSC_EXT.2.2, FCS_DTLSC_EXT.1.2, FCS_DTLSC_EXT.2.2, 2018.08.02 No, Referenced SFR is not being claimed. TD0340 NIT Technical Decision for Handling of the basicConstraint s extension in CA and leaf certificates CPP_FW_V2.0E, CPP_ND_V2.0E FIA_X509_EXT.1.1 2018.08.02 Yes - TD has been applied TD0339 NIT Technical Decision for Making password- based authentication optional in FCS_SSHS_E XT.1.2 CPP_FW_V2.0E, CPP_ND_V2.0E ND SD V2.0, FCS_SSHS_EXT.1.2 2018.08.02 Yes - TD has been applied TD0338 NIT Technical Decision for Access Banner Verification CPP_ND_V2.0E ND SD V2.0, FTA_TAB.1 2018.08.02 Yes - TD has been applied Cisco Catalyst 9200L and 9400 Series Switches Page 24 of 67 TD Identifier TD Name Protection Profiles References Publication Date Applicable? TD0337 NIT Technical Decision for Selections in FCS_SSH*_E XT.1.6 CPP_FW_V2.0E, CPP_ND_V2.0E ND SD V2.0, FCS_SSHC_EXT.1, FCS_SSHS_EXT.1 2018.08.02 Yes - TD has been applied TD0336 NIT Technical Decision for Audit requirements for FCS_SSH*_E XT.1.8 CPP_ND_V2.0E ND SD V2.0, FCS_SSHC_EXT.1.8, FCS_SSHS_EXT.1.8 2018.08.01 Yes - TD has been applied TD0335 NIT Technical Decision for FCS_DTLS Mandatory Cipher Suites CPP_FW_V2.0E, CPP_ND_V2.0E FCS_DTLSC_EXT.1.1, FCS_DTLSC_EXT.2.1, FCS_DTLSS_EXT.1.1, FCS_DTLSS_EXT.2.1, FCS_TLSC_EXT.1.1, FCS_TLSC_EXT.2.1, FCS_TLSS_EXT.1.1, FCS_TLSS_EXT.2.1 2018.08.01 No, Referenced SFR is not being claimed. TD0334 NIT Technical Decision for Testing SSH when password- based authentication is not supported CPP_ND_V2.0E ND SD V2.0, FCS_SSHC_EXT.1.9 2018.08.01 No, Referenced SFR is not being claimed. TD0333 NIT Technical Decision for Applicability of FIA_X509_EX T.3 CPP_FW_V2.0E, CPP_ND_V2.0E ND SD V2.0, FIA_X509_EXT 2018.08.01 Yes - TD has been applied TD0324 NIT Technical Decision for Correction of section numbers in SD Table 1 CPP_ND_V2.0E Table 1 2018.05.18 Yes - TD has been applied TD0323 NIT Technical Decision for DTLS server testing - Empty Certificate Authorities list CPP_ND_V2.0E ND SD V2.0, FCS_DTLSS_EXT.2.7, FCS_DTLSS_EXT.2.8 2018.05.18 No, Referenced SFR is not being claimed. TD0322 NIT Technical Decision for TLS server testing - Empty Certificate Authorities list CPP_ND_V2.0E ND SD V.1.0, ND SD V2.0, FCS_TLSS_EXT.2.4, FCS_TLSS_EXT.2.5 2018.05.18 No, Referenced SFR is not being claimed. Cisco Catalyst 9200L and 9400 Series Switches Page 25 of 67 TD Identifier TD Name Protection Profiles References Publication Date Applicable? TD0321 Protection of NTP communication s CPP_FW_V2.0E, CPP_ND_V2.0E FTP_ITC.1, FPT_STM_EXT.1 2018.05.21 Yes - TD has been applied TD0291 NIT technical decision for DH14 and FCS_CKM.1 CPP_FW_V1.0, CPP_FW_v2.0, CPP_FW_V2.0E, CPP_ND_V1.0, CPP_ND_V2.0, CPP_ND_V2.0E FCS_CKM.1.1, ND SD V1.0, ND SD V2.0 2018.02.03 Yes - TD has been applied TD0290 NIT technical decision for physical interruption of trusted path/channel. CPP_ND_V1.0, CPP_ND_V2.0, CPP_ND_V2.0E FTP_ITC.1, FTP_TRP.1, FPT_ITT.1, ND SD V1.0, ND SD V2.0 2018.02.03 Yes - TD has been applied TD0289 NIT technical decision for FCS_TLSC_E XT.x.1 Test 5e CPP_ND_V1.0, CPP_ND_V2.0, CPP_ND_V2.0E FCS_TLSC_EXT.1.1, FCS_TLSC_EXT.2.1, FCS_DTLSC_EXT.1.1 (only ND SD V2.0), FCS_DTLSC_EXT.2.1 (only ND SD V2.0) 2018.02.03 No, Referenced SFR is not being claimed. TD0281 NIT Technical Decision for Testing both thresholds for SSH rekey CPP_ND_V1.0, CPP_ND_V2.0, CPP_ND_V2.0E FCS_SSHC_EXT.1.8, FCS_SSHS_EXT.1.8, ND SD V1.0, ND SD V2.0 2018.01.05 Yes - TD has been applied TD0259 NIT Technical Decision for Support for X509 ssh rsa authentication IAW RFC 6187 CPP_FW_v2.0, CPP_FW_V2.0E, CPP_ND_V2.0, CPP_ND_V2.0E FCS_SSHC_EXT.1.5/FC S_SSHS_EXT.1.5 2017.11.13 Yes - TD has been applied TD0257 NIT Technical Decision for Updating FCS_DTLSC_ EXT.x.2/FCS_ TLSC_EXT.x. 2 Tests 1-4 CPP_ND_V1.0, CPP_ND_V2.0, CPP_ND_V2.0E ND SD V1.0, ND SD V2.0, FCS_DTLSC_EXT.1.2/F CS_DTLSC_EXT.2.2 Tests 1-4 (ND SD V2.0), FCS_TLSC_EXT.1.2/FC S_TLSC_EXT.2.2, Tests 1-4 (ND SD V1.0, ND SD V2.0) 2017.11.13 No, Referenced SFR is not being claimed. TD0256 NIT Technical Decision for Handling of TLS connections with and without mutual authentication CPP_ND_V1.0, CPP_ND_V2.0, CPP_ND_V2.0E ND SD V1.0, ND SD V2.0, FCS_DTLSC_EXT.2.5 (ND SD V2.0), FCS_TLSC_EXT.2 (ND SD V1.0, ND SD V2.0) 2017.11.13 No, Referenced SFR is not being claimed. Cisco Catalyst 9200L and 9400 Series Switches Page 26 of 67 TD Identifier TD Name Protection Profiles References Publication Date Applicable? TD0228 NIT Technical Decision for CA certificates - basicConstraint s validation CPP_FW_V1.0, CPP_ND_V1.0, CPP_ND_V2.0, CPP_ND_V2.0E ND SD V1.0, ND SD V2.0, FIA_X509_EXT.1.2 2018.06.15 Yes - TD has been applied Table 11 Protection Profiles Protection Profile Version Date collaborative Protection Profile for Network Devices (NDcPP) + Errata 2.0e 14 March 2018 2.2.1 Protection Profile Additions The ST claims exact conformance to the collaborative Protection Profile for Network Devices (NDcPP) +Errata 20180314, Version 2.0e and does not include any additions to the functionality described in the Protection Profile. 2.3 Protection Profile Conformance Claim Rationale 2.3.1 TOE Appropriateness The TOE provides all of the functionality at a level of security commensurate with that identified in the U.S. Government Protection Profile: • collaborative Protection Profile for Network Devices (NDcPP) + Errata 20180314, Version 2.0e 2.3.2 TOE Security Problem Definition Consistency The Assumptions, Threats, and Organization Security Policies included in the Security Target represent the Assumptions, Threats, and Organization Security Policies specified in the collaborative Protection Profile for Network Devices (NDcPP) + Errata 20180314, Version 2.0e for which conformance is claimed verbatim. All concepts covered in the Protection Profile Security Problem Definition are included in the Security Target Statement of Security Objectives Consistency. The Security Objectives included in the Security Target represent the Security Objectives specified in the NDcPPv2.0e for which conformance is claimed verbatim. All concepts covered in the Protection Profile’s Statement of Security Objectives are included in the Security Target. 2.3.3 Statement of Security Requirements Consistency The Security Functional Requirements included in the Security Target represent the Security Functional Requirements specified in the NDcPP+ Errata 20180314, Version 2.0e for which conformance is claimed verbatim. All concepts covered in the Protection Profile’s Statement of Security Requirements are included in this Security Target. Additionally, the Security Assurance Cisco Catalyst 9200L and 9400 Series Switches Page 27 of 67 Requirements included in this Security Target are identical to the Security Assurance Requirements included in NDcPP + Errata 20180314, Version 2.0e. Cisco Catalyst 9200L and 9400 Series Switches Page 28 of 67 3 SECURITY PROBLEM DEFINITION This chapter identifies the following: • Significant assumptions about the TOE’s operational environment. • IT related threats to the organization countered by the TOE. • Environmental threats requiring controls to provide sufficient protection. • Organizational security policies for the TOE as appropriate. This document identifies assumptions as A.assumption with “assumption” specifying a unique name. Threats are identified as T.threat with “threat” specifying a unique name. Organizational Security Policies (OSPs) are identified as P.osp with “osp” specifying a unique name. 3.1 Assumptions The specific conditions listed in the following subsections are assumed to exist in the TOE’s environment. These assumptions include both practical realities in the development of the TOE security requirements and the essential environmental conditions on the use of the TOE. Table 12 TOE Assumptions Assumption Assumption Definition A.PHYSICAL_PROTECTION The network device is assumed to be physically protected in its operational environment and not subject to physical attacks that compromise the security and/or interfere with the device’s physical interconnections and correct operation. This protection is assumed to be sufficient to protect the device and the data it contains. As a result, the cPP will not include any requirements on physical tamper protection or other physical attack mitigations. The cPP will not expect the product to defend against physical access to the device that allows unauthorized entities to extract data, bypass other controls, or otherwise manipulate the device. A.LIMITED_FUNCTIONALITY The device is assumed to provide networking functionality as its core function and not provide functionality/ services that could be deemed as general purpose computing. For example the device should not provide computing platform for general purpose applications (unrelated to networking functionality). A.NO_THRU_TRAFFIC_PROTECTION A standard/generic network device does not provide any assurance regarding the protection of traffic that traverses it. The intent is for the network device to protect data that originates on or is destined to the device itself, to include administrative data and audit data. Traffic that is traversing the network device, destined for another network entity, is not covered by the ND cPP. It is assumed that this protection will be covered by cPPs for particular types of network devices (e.g., firewall). A.TRUSTED_ADMINISTRATOR The Security Administrator(s) for the network device are assumed to be trusted and to act in the best interest of security for the organization. This includes being appropriately trained, following policy, and adhering to guidance documentation. Administrators are trusted to ensure passwords/credentials have sufficient strength and entropy and to lack malicious intent when administering the device. The network device is not expected to be capable of defending against a malicious administrator that actively works to bypass or compromise the security of the device. Cisco Catalyst 9200L and 9400 Series Switches Page 29 of 67 Assumption Assumption Definition A.RESIDUAL_INFORMATION The Administrator must ensure that there is no unauthorized access possible for sensitive residual information (e.g. cryptographic keys, keying material, PINs, passwords etc.) on networking equipment when the equipment is discarded or removed from its operational environment. A.REGULAR_UPDATES The network device firmware and software is assumed to be updated by an administrator on a regular basis in response to the release of product updates due to known vulnerabilities. A.ADMIN_CREDENTIALS_SECURE The administrator’s credentials (private key) used to access the network device are protected by the platform on which they reside. 3.2 Threats The following table lists the threats addressed by the TOE and the IT Environment. The assumed level of expertise of the attacker for all the threats identified below is Enhanced-Basic. Table 13 Threats Threat Threat Definition T.UNAUTHORIZED_ADMINISTRATO R_ACCESS Threat agents may attempt to gain Administrator access to the network device by nefarious means such as masquerading as an Administrator to the device, masquerading as the device to an Administrator, replaying an administrative session (in its entirety, or selected portions), or performing man-in-the-middle attacks, which would provide access to the administrative session, or sessions between network devices. Successfully gaining Administrator access allows malicious actions that compromise the security functionality of the device and the network on which it resides. T.WEAK_CRYPTOGRAPHY Threat agents may exploit weak cryptographic algorithms or perform a cryptographic exhaust against the key space. Poorly chosen encryption algorithms, modes, and key sizes will allow attackers to compromise the algorithms, or brute force exhaust the key space and give them unauthorized access allowing them to read, manipulate and/or control the traffic with minimal effort. T.UNTRUSTED_COMMUNICATION_ CHANNELS Threat agents may attempt to target network devices that do not use standardized secure tunnelling protocols to protect the critical network traffic. Attackers may take advantage of poorly designed protocols or poor key management to successfully perform man-in- the-middle attacks, replay attacks, etc. Successful attacks will result in loss of confidentiality and integrity of the critical network traffic, and potentially could lead to a compromise of the network device itself. T.WEAK_AUTHENTICATION_ENDP OINTS Threat agents may take advantage of secure protocols that use weak methods to authenticate the endpoints – e.g., shared password that is guessable or transported as plaintext. The consequences are the same as a poorly designed protocol, the attacker could masquerade as the administrator or another device, and the attacker could insert themselves into the network stream and perform a man-in-the- middle attack. The result is the critical network traffic is exposed and there could be a loss of confidentiality and integrity, and potentially the network device itself could be compromised. Cisco Catalyst 9200L and 9400 Series Switches Page 30 of 67 Threat Threat Definition T.UPDATE_COMPROMISE Threat agents may attempt to provide a compromised update of the software or firmware which undermines the security functionality of the device. Non-validated updates or updates validated using non- secure or weak cryptography leave the update firmware vulnerable to surreptitious alteration. T.UNDETECTED_ACTIVITY Threat agents may attempt to access, change, and/or modify the security functionality of the network device without Administrator awareness. This could result in the attacker finding an avenue (e.g., misconfiguration, flaw in the product) to compromise the device and the Administrator would have no knowledge that the device has been compromised. T.SECURITY_FUNCTIONALITY_CO MPROMISE Threat agents may compromise credentials and device data enabling continued access to the network device and its critical data. The compromise of credentials includes replacing existing credentials with an attacker’s credentials, modifying existing credentials, or obtaining the Administrator or device credentials for use by the attacker. T.PASSWORD_CRACKING Threat agents may be able to take advantage of weak administrative passwords to gain privileged access to the device. Having privileged access to the device provides the attacker unfettered access to the network traffic, and may allow them to take advantage of any trust relationships with other network devices. T.SECURITY_FUNCTIONALITY_FAI LURE An external, unauthorized entity could make use of failed or compromised security functionality and might therefore subsequently use or abuse security functions without prior authentication to access, change or modify device data, critical network traffic or security functionality of the device. 3.3 Organizational Security Policies The following table lists the Organizational Security Policies imposed by an organization to address its security needs. Table 14 Organizational Security Policies Policy Name Policy Definition P.ACCESS_BANNER The TOE shall display an initial banner describing restrictions of use, legal agreements, or any other appropriate information to which users consent by accessing the TOE. Cisco Catalyst 9200L and 9400 Series Switches Page 31 of 67 4 SECURITY OBJECTIVES This Chapter identifies the security objectives of the TOE and the IT Environment. The security objectives identify the responsibilities of the TOE and the TOE’s IT environment in meeting the security needs. • This document identifies objectives of the TOE as O.objective with objective specifying a unique name. Objectives that apply to the IT environment are designated as OE.objective with objective specifying a unique name. 4.1 Security Objectives for the TOE The collaborative Protection Profile for Network Devices + Errata 20180314 v2.0e does not define any security objectives for the TOE. 4.2 Security Objectives for the Environment All of the assumptions stated in section 3.1 are considered to be security objectives for the environment. The following are the Protection Profile non-IT security objectives, which, in addition to those assumptions, are to be satisfied without imposing technical requirements on the TOE. That is, they will not require the implementation of functions in the TOE hardware and/or software. Thus, they will be satisfied largely through application of procedural or administrative measures. Table 15 Security Objectives for the Environment Environment Security Objective IT Environment Security Objective Definition OE.PHYSICAL Physical security, commensurate with the value of the TOE and the data it contains, is provided by the environment. OE.NO_GENERAL_PURPOSE There are no general-purpose computing capabilities (e.g., compilers or user applications) available on the TOE, other than those services necessary for the operation, administration and support of the TOE. OE.NO_THRU_TRAFFIC_PROTECTION The TOE does not provide any protection of traffic that traverses it. It is assumed that protection of this traffic will be covered by other security and assurance measures in the operational environment. OE.TRUSTED_ADMIN Security Administrators are trusted to follow and apply all guidance documentation in a trusted manner. OE.UPDATES The TOE firmware and software is updated by an Administrator on a regular basis in response to the release of product updates due to known vulnerabilities. OE.ADMIN_CREDENTIALS_SECURE The Administrator’s credentials (private key) used to access the TOE must be protected on any other platform on which they reside. OE.RESIDUAL_INFORMATION The Security Administrator ensures that there is no unauthorized access possible for sensitive residual information (e.g. cryptographic keys, keying material, PINs, passwords etc.) on networking equipment when the equipment is discarded or removed from its operational environment. Cisco Catalyst 9200L and 9400 Series Switches Page 32 of 67 5 SECURITY REQUIREMENTS This section identifies the Security Functional Requirements for the TOE. The Security Functional Requirements included in this section are derived from Part 2 of the Common Criteria for Information Technology Security Evaluation, Version 3.1, Revision 4, dated: September 2012 and all international interpretations. 5.1 Conventions The CC defines operations on Security Functional Requirements: assignments, selections, assignments within selections and refinements. This document uses the following font conventions to identify the operations defined by the CC: • Unaltered SFRs are stated in the form used in [CC2] or their extended component definition (ECD); • Refinement made by PP author: Indicated with bold text and strikethroughs; • Selection wholly or partially completed in the PP: the selection values (i.e. the selection values adopted in the PP or the remaining selection values available for the ST) are indicated with underlined text o e.g. “[selection: disclosure, modification, loss of use]” in [CC2] or an ECD might become “disclosure” (completion) or “[selection: disclosure, modification]” (partial completion) in the PP; • Assignment wholly or partially completed in the PP: indicated with italicized text • Assignment completed within a selection in the PP: the completed assignment text is indicated with italicized and underlined text o e.g. “[selection: change_default, query, modify, delete, [assignment: other operations]]” in [CC2] or an ECD might become “change_default, select_tag” (completion of both selection and assignment) or “[selection: change_default, select_tag, select_value]” (partial completion of selection, and completion of assignment) in the PP; • Iteration: indicated by adding a string starting with “/” (e.g. “FCS_COP.1/Hash”). Extended SFRs are identified by having a label “EXT” at the end of the SFR name. 5.2 TOE Security Functional Requirements This section identifies the Security Functional Requirements for the TOE. The TOE Security Functional Requirements that appear in the following table are described in more detail in the following subsections. Table 16 Security Functional Requirements Class Name Component Identification Component Name FAU: Security audit FAU_GEN.1 Audit data generation FAU_GEN.2 User Identity Association FAU_STG_EXT.1 Protected Audit Event Storage FCS: Cryptographic support FCS_CKM.1 Cryptographic Key Generation (for asymmetric keys) FCS_CKM.2 Cryptographic Key Establishment Cisco Catalyst 9200L and 9400 Series Switches Page 33 of 67 Class Name Component Identification Component Name FCS_CKM.4 Cryptographic Key Destruction FCS_COP.1/DataEncryption Cryptographic Operation (AES Data Encryption/ Decryption) FCS_COP.1/SigGen Cryptographic Operation (Signature Generation and Verification) FCS_COP.1/Hash Cryptographic Operation (Hash Algorithm) FCS_COP.1/KeyedHash Cryptographic Operation (Keyed Hash Algorithm) FCS_RBG_EXT.1 Random Bit Generation FCS_IPSEC_EXT.1 IPsec Protocol FCS_SSHS_EXT.1 SSH Server Protocol FIA: Identification and authentication FIA_AFL.1 Authentication Failure Management FIA_PMG_EXT.1 Password Management FIA_UIA_EXT.1 User Identification and Authentication FIA_UAU_EXT.2 Password-based Authentication Mechanism FIA_UAU.7 Protected Authentication Feedback FIA_X509_EXT.1/Rev X.509 Certificate Validation FIA_X509_EXT.2 X.509 Certificate Authentication FIA_X509_EXT.3 X.509 Certificate Requests FMT: Security management FMT_MOF.1/ManualUpdate Management of security functions behaviour FMT_MTD.1/CoreData Management of TSF Data FMT_MTD.1/CryptoKeys Management of TSF Data FMT_SMF.1 Specification of Management Functions FMT_SMR.2 Restrictions on Security Roles FPT: Protection of the TSF FPT_APW_EXT.1 Protection of Administrator Passwords FPT_SKP_EXT.1 Protection of TSF Data (for reading of all pre- shared, symmetric and private keys) FPT_STM_EXT.1 Reliable Time Stamps FPT_TST_EXT.1 TSF Testing FPT_TUD_EXT.1 Trusted Update FTA: TOE Access FTA_SSL_EXT.1 TSF-initiated Session Locking FTA_SSL.3 TSF-initiated Termination FTA_SSL.4 User-initiated Termination FTA_TAB.1 Default TOE Access Banners FTP: Trusted Path/Channels FTP_ITC.1 Inter-TSF trusted channel FTP_TRP.1/Admin Trusted Path 5.2.1 Security audit (FAU) 5.2.1.1 FAU_GEN.1 Audit data generation FAU_GEN.1.1 The TSF shall be able to generate an audit record of the following auditable events: a) Start-up and shut-down of the audit functions; b) All auditable events for the not specified level of audit; and c) All administrator actions comprising: • Administrative login and logout (name of user account shall be logged if individual user accounts are required for administrators). • Changes to TSF data related to configuration changes (in addition to the information that a change occurred it shall be logged what has been changed. Cisco Catalyst 9200L and 9400 Series Switches Page 34 of 67 • Generating/import of, changing, or deleting of cryptographic keys (in addition to the action itself a unique key name or key reference shall be logged). • Resetting passwords (name of related user account shall be logged). • [no other actions]; d) Specifically defined auditable events listed in Table 17 Auditable Events. FAU_GEN.1.2 The TSF shall record within each audit record at least the following information: • Date and time of the event, type of event, subject identity, and the outcome (success or failure) of the event; and • For each audit event type, based on the auditable event definitions of the functional components included in the cPP/ST, information specified in column three of Table 17. Table 17 Auditable Events SFR Auditable Event Additional Audit Record Contents FAU_GEN.1 None. None. FAU_GEN.2 None. None. FAU_STG_EXT.1 None. None. FCS_CKM.1 None. None. FCS_CKM.2 None. None. FCS_CKM.4 None. None. FCS_COP.1/DataEncryption None. None. FCS_COP.1/SigGen None. None. FCS_COP.1/Hash None. None. FCS_COP.1/KeyedHash None. None. FCS_IPSEC_EXT.1 Failure to establish an IPsec SA. Reason for failure. FCS_SSHS_EXT.1 Failure to establish an SSH session Reason for failure. FCS_RBG_EXT.1 None. None. FIA_AFL.1 Unsuccessful login attempts limit is met or exceeded. Origin of the attempt (e.g., IP address). FIA_PMG_EXT.1 None. None. FIA_UIA_EXT.1 All use of the identification and authentication mechanism. Origin of the attempt (e.g., IP address). FIA_UAU_EXT.2 All use of the identification and authentication mechanism. Origin of the attempt (e.g., IP address). FIA_UAU.7 None. None. FIA_X509_EXT.1/Rev Unsuccessful attempt to validate a certificate Reason for failure FIA_X509_EXT.2 None. None. FIA_X509_EXT.3 None. None. FMT_MOF.1/ ManualUpdate Any attempt to initiate a manual update None. FMT_MTD.1/CoreData All management activities of TSF data. None. FMT_MTD.1_CryptoKeys Management of cryptographic keys None FMT_SMF.1 None. None. FMT_SMR.2 None. None. FPT_SKP_EXT.1 None. None. FPT_APW_EXT.1 None. None. FPT_STM_EXT.1 Discontinuous changes to time – either Administrator actuated or changed via an automated process. (Note that no continuous changes to For discontinuous changes to time: The old and new values for the time. Origin of the attempt to change time for success and failure (e.g., IP address). Cisco Catalyst 9200L and 9400 Series Switches Page 35 of 67 SFR Auditable Event Additional Audit Record Contents time need to be logged. See also application note on FPT_STM_EXT.1) FPT_TST_EXT.1 None. None. FPT_TUD_EXT.1 Initiation of update; result of the update attempt (success and failure) None. FTA_SSL_EXT.1 The termination of a local session by the session locking mechanism. None. FTA_SSL.3 The termination of a remote session by the session locking mechanism. None. FTA_SSL.4 The termination of an interactive session. None. FTA_TAB.1 None. None. FTP_ITC.1 Initiation of the trusted channel. Termination of the trusted channel. Failure of the trusted channel functions. Identification of the initiator and target of failed trusted channels establishment attempt FTP_TRP.1/Admin Initiation of the trusted channel. Termination of the trusted channel. Failures of the trusted path functions. None. 5.2.1.2 FAU_GEN.2 User Identity Association FAU_GEN.2.1 For audit events resulting from actions of identified users, the TSF shall be able to associate each auditable event with the identity of the user that caused the event. 5.2.1.3 FAU_STG_EXT.1 Protected Audit Event Storage FAU_STG_EXT.1.1 The TSF shall be able to transmit the generated audit data to an external IT entity using a trusted channel according to FTP_ITC.1. FAU_STG_EXT.1.2 The TSF shall be able to store generated audit data on the TOE itself. FAU_STG_EXT.1.3 The TSF shall [overwrite previous audit records according to the following rule: [when allotted space has reached its threshold] when the local storage space for audit data is full. 5.2.2 Cryptographic Support (FCS) 5.2.2.1 FCS_CKM.1 Cryptographic Key Generation (Refinement) FCS_CKM.1.1 The TSF shall generate asymmetric cryptographic keys in accordance with a specified cryptographic key generation algorithm: [ • RSA schemes using cryptographic key sizes of 2048-bit or greater that meet the following: FIPS PUB 186-4, “Digital Signature Standard (DSS)”, Appendix B.3; Cisco Catalyst 9200L and 9400 Series Switches Page 36 of 67 • FFC Schemes using Diffie-Hellman group 14 that meet the following: RFC 3526, Section 3; ] and specified cryptographic key sizes [assignment: cryptographic key sizes] that meet the following: [assignment: list of standards]. 5.2.2.2 FCS_CKM.2 Cryptographic Key Establishment (Refinement) FCS_CKM.2.1 The TSF shall perform cryptographic key establishment in accordance with a specified cryptographic key establishment method: [ • Key establishment scheme using Diffie-Hellman group 14 that meets the following: RFC 3526, Section 3; ] that meets the following: [assignment: list of standards]. 5.2.2.3 FCS_CKM.4 Cryptographic Key Destruction FCS_CKM.4.1 The TSF shall destroy cryptographic keys in accordance with a specified cryptographic key destruction method [ • For plaintext keys in volatile storage, the destruction shall be executed by a [single overwrite consisting of [zeroes]; • For plaintext keys in non-volatile storage, the destruction shall be executed by the invocation of an interface provided by a part of the TSF that [ o logically addresses the storage location of the key and performs a [single] overwrite consisting of [zeroes]] that meets the following: No Standard. 5.2.2.4 FCS_COP.1/DataEncryption Cryptographic Operation (AES Data Encryption/Decryption) FCS_COP.1.1/DataEncryption The TSF shall perform encryption/decryption in accordance with a specified cryptographic algorithm AES used in [CBC] mode and cryptographic key sizes [128 bits, 256 bits] that meet the following: AES as specified in ISO 18033-3, [CBC as specified in ISO 10116]. 5.2.2.5 FCS_COP.1/SigGen Cryptographic Operation (Signature Generation and Verification) FCS_COP.1.1/SigGen The TSF shall perform cryptographic signature services (generation and verification) in accordance with a specified cryptographic algorithm [ • RSA Digital Signature Algorithm and cryptographic key sizes (modulus) [2048 bits or greater], ] that meet the following: [ • For RSA schemes: FIPS PUB 186-4, “Digital Signature Standard (DSS)”, Section 5.5, using PKCS #1 v2.1 Signature Schemes RSASSA-PSS and/or RSASSA-PKCS1v1_5; ISO/IEC 9796-2, Digital signature scheme 2 or Digital Signature scheme 3, Cisco Catalyst 9200L and 9400 Series Switches Page 37 of 67 ]. 5.2.2.6 FCS_COP.1/Hash Cryptographic Operation (Hash Algorithm) FCS_COP.1.1/Hash The TSF shall perform cryptographic hashing services in accordance with a specified cryptographic algorithm [SHA-1, SHA-256, SHA-512] and cryptographic key sizes [assignment: cryptographic key sizes] and message digest sizes [160, 256, 512] bits that meet the following: ISO/IEC 10118-3:2004. 5.2.2.7 FCS_COP.1/KeyedHash Cryptographic Operation (Keyed Hash Algorithm) FCS_COP.1.1/KeyedHash The TSF shall perform keyed-hash message authentication in accordance with a specified cryptographic algorithm [HMAC-SHA-1, HMAC-SHA-256, HMAC- SHA-512] and cryptographic key sizes [160-bit, 256-bit, 512-bit] and message digest sizes [160, 256, 512] bits that meet the following: ISO/IEC 9797-2:2011, Section 7 “MAC Algorithm 2”. 5.2.2.8 FCS_IPSEC_EXT.1 IPsec Protocol FCS_IPSEC_EXT.1.1 The TSF shall implement the IPsec architecture as specified in RFC 4301. FCS_IPSEC_EXT.1.2 The TSF shall have a nominal, final entry in the SPD that matches anything that is otherwise unmatched, and discards it. FCS_IPSEC_EXT.1.3 The TSF shall implement [tunnel mode, transport mode]. FCS_IPSEC_EXT.1.4 The TSF shall implement the IPsec protocol ESP as defined by RFC 4303 using the cryptographic algorithms [AES-CBC-128, AES-CBC-256 (specified by RFC 3602)] together with a Secure Hash Algorithm (SHA)-based HMAC [HMAC-SHA-1, HMAC-SHA-256, HMAC-SHA-512] and [no other algorithm]. FCS_IPSEC_EXT.1.5 The TSF shall implement the protocol: [ • IKEv1, using Main Mode for Phase 1 exchanges, as defined in RFCs 2407, 2408, 2409, RFC 4109, [no other RFCs for extended sequence numbers], and [RFC 4868 for hash functions]]. • IKEv2 as defined in RFCs 5996 [with no support for NAT traversal], and [RFC 4868 for hash functions] ]. FCS_IPSEC_EXT.1.6 The TSF shall ensure the encrypted payload in the [IKEv1, IKEv2] protocol uses the cryptographic algorithms [AES-CBC-128, AES-CBC-256 (as specified in RFC 3602)]. FCS_IPSEC_EXT.1.7 The TSF shall ensure that [ • IKEv1 Phase 1 SA lifetimes can be configured by an Security Administrator based on [ o length of time, where the time values can configured within [1-24] hours; Cisco Catalyst 9200L and 9400 Series Switches Page 38 of 67 ]; • IKEv2 SA lifetimes can be configured by an Security Administrator based on [ o length of time, where the time values can configured within [1-24] hours; ] ]. FCS_IPSEC_EXT.1.8 The TSF shall ensure that [ • IKEv1 Phase 2 SA lifetimes can be configured by an Security Administrator based on [ o number of bytes o length of time, where the time values can configured within [1-8] hours; ]; • IKEv2 Child SA lifetimes can be configured by an Security Administrator based on [ o number of bytes o length of time, where the time values can configured within [1-8] hours; ]. FCS_IPSEC_EXT.1.9 The TSF shall generate the secret value x used in the IKE Diffie-Hellman key exchange (“x” in gx mod p) using the random bit generator specified in FCS_RBG_EXT.1 and having a length of at least [224 (for DH Group 14)] bits. FCS_IPSEC_EXT.1.10 The TSF shall generate nonces used in [IKEv1, IKEv2] exchanges of length • [according to the security strength associated with the negotiated Diffie-Hellman group ]. FCS_IPSEC_EXT.1.11 The TSF shall ensure that IKE protocols implement DH Group(s) [14 (2048-bit MODP)]. FCS_IPSEC_EXT.1.12 The TSF shall be able to ensure by default that the strength of the symmetric algorithm (in terms of the number of bits in the key) negotiated to protect the [IKEv1 Phase 1, IKEv2 IKE_SA] connection is greater than or equal to the strength of the symmetric algorithm (in terms of the number of bits in the key) negotiated to protect the [IKEv1 Phase 2, IKEv2 CHILD_SA] connection. FCS_IPSEC_EXT.1.13 The TSF shall ensure that all IKE protocols perform peer authentication using [RSA] that use X.509v3 certificates that conform to RFC 4945 and [Pre-shared Keys]. FCS_IPSEC_EXT.1.14 The TSF shall only establish a trusted channel if the presented identifier in the received certificate matches the configured reference identifier, where the presented and reference identifiers are of the following fields and types: [CN: Fully Qualified Domain Name (FQDN), Distinguished Name (DN)] and [no other reference identifier type]. Cisco Catalyst 9200L and 9400 Series Switches Page 39 of 67 5.2.2.9 FCS_RBG_EXT.1 Random Bit Generation FCS_RBG_EXT.1.1 The TSF shall perform all deterministic random bit generation services in accordance with ISO/IEC 18031:2011 using [CTR_DRBG (AES)]. FCS_RBG_EXT.1.2 The deterministic RBG shall be seeded by at least one entropy source that accumulates entropy from [[1] hardware based noise source] with minimum of [256 bits] of entropy at least equal to the greatest security strength, according to ISO/IEC 18031:2011 Table C.1 “Security Strength Table for Hash Functions”, of the keys and hashes that it will generate. 5.2.2.10 FCS_SSHS_EXT.1 SSH Server Protocol FCS_SSHS_EXT.1.1 The TSF shall implement the SSH protocol that complies with RFCs [4251, 4252, 4253, 4254]. FCS_SSHS_EXT.1.2 The TSF shall ensure that the SSH protocol implementation supports the following authentication methods as described in RFC 4252: public key-based, [password based]. FCS_SSHS_EXT.1.3 The TSF shall ensure that, as described in RFC 4253, packets greater than [65,535 bytes] bytes in an SSH transport connection are dropped. FCS_SSHS_EXT.1.4 The TSF shall ensure that the SSH transport implementation uses the following encryption algorithms and rejects all other encryption algorithms: [aes128-cbc, aes256- cbc]. FCS_SSHS_EXT.1.5 The TSF shall ensure that the SSH public-key based authentication implementation uses [ssh-rsa] as its public key algorithm(s) and rejects all other public key algorithms. FCS_SSHS_EXT.1.6 The TSF shall ensure that the SSH transport implementation uses [hmac- sha1, hmac-sha1-96] as its data integrity MAC algorithm(s) and rejects all other MAC algorithm(s). FCS_SSHS_EXT.1.7 The TSF shall ensure that [diffie-hellman-group14-sha1] and [no other methods] are the only allowed key exchange methods used for the SSH protocol. FCS_SSHS_EXT.1.8 The TSF shall ensure that within SSH connections the same session keys are used for a threshold of no longer than one hour, and no more than one gigabyte of transmitted data. After either of the thresholds are reached a rekey needs to be performed. Cisco Catalyst 9200L and 9400 Series Switches Page 40 of 67 5.2.3 Identification and authentication (FIA) 5.2.3.1 FIA_AFL.1 Authentication Failure Management FIA_AFL.1.1 The TSF shall detect when an Administrator configurable positive integer within [1-3] unsuccessful authentication attempts occur related to Administrators attempting to authenticate remotely using a password. FIA_AFL.1.2 When the defined number of unsuccessful authentication attempts has been [met], the TSF shall [prevent the offending remote Administrator from successfully establishing a remote session using any authentication method that involves a password until [an Authorized Administrator unlocks the locked user account] is taken by an Administrator]. 5.2.3.2 FIA_PMG_EXT.1 Password Management FIA_PMG_EXT.1.1 The TSF shall provide the following password management capabilities for administrative passwords: a) Passwords shall be able to be composed of any combination of upper and lower case letters, numbers, and the following special characters: [“!”, “@”, “#”, “$”, “%”, “^”, “&”, “*”, “(“,”)”]; b) Minimum password length shall be configurable to [15] and [15]. 5.2.3.3 FIA_UIA_EXT.1 User Identification and Authentication FIA_UIA_EXT.1.1 The TSF shall allow the following actions prior to requiring the non-TOE entity to initiate the identification and authentication process: • Display the warning banner in accordance with FTA_TAB.1; • [no other actions]. FIA_UIA_EXT.1.2 The TSF shall require each administrative user to be successfully identified and authenticated before allowing any other TSF-mediated action on behalf of that administrative user. 5.2.3.4 FIA_UAU_EXT.2 Password-based Authentication Mechanism FIA_UAU_EXT.2.1 The TSF shall provide a local [password-based] authentication mechanism, to perform local administrative user authentication. 5.2.3.5 FIA_UAU.7 Protected Authentication Feedback FIA_UAU.7.1 The TSF shall provide only obscured feedback to the administrative user while the authentication is in progress at the local console. Cisco Catalyst 9200L and 9400 Series Switches Page 41 of 67 5.2.3.6 FIA_X509_EXT.1/Rev X.509 Certificate Validation FIA_X509_EXT.1.1/Rev The TSF shall validate certificates in accordance with the following rules: • RFC 5280 certificate validation and certificate path validation supporting a minimum path length of three certificates. • The certificate path must terminate with a trusted CA certificate. • The TSF shall validate a certification path by ensuring that all CA certificates in the certification path contain the basicConstraints extension with the CA flag set to TRUE. • The TSF shall validate the revocation status of the certificate using [Certificate Revocation List (CRL) as specified in RFC 5759 Section 5, Online Certificate Status Protocol (OCSP) as specified in RFC 6960]. • The TSF shall validate the extendedKeyUsage field according to the following rules: o Certificates used for trusted updates and executable code integrity verification shall have the Code Signing purpose (id-kp 3 with OID 1.3.6.1.5.5.7.3.3) in the extendedKeyUsage field. o Server certificates presented for TLS shall have the Server Authentication purpose (id-kp 1 with OID 1.3.6.1.5.5.7.3.1) in the extendedKeyUsage field. o Client certificates presented for TLS shall have the Client Authentication purpose (id- kp 2 with OID 1.3.6.1.5.5.7.3.2) in the extendedKeyUsage field. o OCSP certificates presented for OCSP responses shall have the OCSP Signing purpose (id-kp 9 with OID 1.3.6.1.5.5.7.3.9) in the extendedKeyUsage field. FIA_X509_EXT.1.2/Rev The TSF shall only treat a certificate as a CA certificate if the basicConstraints extension is present and the CA flag is set to TRUE. 5.2.3.7 FIA_X509_EXT.2 X.509 Certificate Authentication FIA_X509_EXT.2.1 The TSF shall use X.509v3 certificates as defined by RFC 5280 to support authentication for [IPsec], and [no additional uses]. FIA_X509_EXT.2.2 When the TSF cannot establish a connection to determine the validity of a certificate, the TSF shall [not accept the certificate]. 5.2.3.8 FIA_X509_EXT.3 X.509 Certificate Requests FIA_X509_EXT.3.1 The TSF shall generate a Certificate Request Message as specified by RFC 2986 and be able to provide the following information in the request: public key and [Common Name, Organization, Organizational Unit, Country]. FIA_X509_EXT.3.2 The TSF shall validate the chain of certificates from the Root CA upon receiving the CA Certificate Response. Cisco Catalyst 9200L and 9400 Series Switches Page 42 of 67 5.2.4 Security management (FMT) 5.2.4.1 FMT_MOF.1/ManualUpdate Management of security functions behaviour FMT_MOF.1/ManualUpdate The TSF shall restrict the ability to enable the functions to perform manual update to Security Administrators. 5.2.4.2 FMT_MTD.1/CoreData Management of TSF Data FMT_MTD.1/CoreData The TSF shall restrict the ability to manage the TSF data to Security Administrators. 5.2.4.3 FMT_MTD.1/CryptoKeys Management of TSF data FMT_MTD.1.1/CryptoKeys The TSF shall restrict the ability to manage the cryptographic keys to Security Administrators. 5.2.4.4 FMT_SMF.1 Specification of Management Functions FMT_SMF.1.1 The TSF shall be capable of performing the following management functions: • Ability to administer the TOE locally and remotely; • Ability to configure the access banner; • Ability to configure the session inactivity time before session termination or locking; • Ability to update the TOE, and to verify the updates using [hash comparison] capability prior to installing those updates; • Ability to configure the authentication failure parameters for FIA_AFL.1; • [ o Ability to configure audit behaviour; o Ability to configure the list of TOE-provided services available before an entity is identified and authenticated, as specified in FIA_UIA_EXT.1; o Ability to configure the cryptographic functionality; o Ability to configure thresholds for SSH rekeying; o Ability to configure the lifetime for IPsec SAs; o Ability to re-enable an Administrator account; o Ability to set the time which is used for time-stamps; o Ability to configure the reference identifier for the peer; ] ]. 5.2.4.5 FMT_SMR.2 Restrictions on Security Roles FMT_SMR.2.1 The TSF shall maintain the roles: • Security Administrator. FMT_SMR.2.2 The TSF shall be able to associate users with roles. Cisco Catalyst 9200L and 9400 Series Switches Page 43 of 67 FMT_SMR.2.3 The TSF shall ensure that the conditions • The Security Administrator role shall be able to administer the TOE locally; • The Security Administrator role shall be able to administer the TOE remotely are satisfied. 5.2.5 Protection of the TSF (FPT) 5.2.5.1 FPT_APW_EXT.1: Protection of Administrator Passwords FPT_APW_EXT.1.1 The TSF shall store passwords in non-plaintext form. FPT_APW_EXT.1.2 The TSF shall prevent the reading of plaintext passwords. 5.2.5.2 FPT_SKP_EXT.1 Protection of TSF Data (for reading of all pre-shared, symmetric and private keys) FPT_SKP_EXT.1.1 The TSF shall prevent reading of all pre-shared keys, symmetric keys, and private keys. 5.2.5.3 FPT_STM.EXT.1 Reliable time stamps FPT_STM_EXT.1.1 The TSF shall be able to provide reliable time stamps for its own use. FPT_STM_EXT.1.2 The TSF shall [allow the Security Administrator to set the time]. 5.2.5.4 FPT_TST_EXT.1: TSF Testing FPT_TST_EXT.1.1 The TSF shall run a suite of the following self-tests [during initial start-up (on power on), periodically during normal operation] to demonstrate the correct operation of the TSF: [ • Software Self-Integrity Test • RNG/DRBG Known Answer Test • AES Known Answer Test • RSA Signature Known Answer Test (both signature/verification) • HMAC Known Answer Test • SHA-1/256/512 Known Answer Test 5.2.5.5 FPT_TUD_EXT.1 Trusted Update FPT_TUD_EXT.1.1 The TSF shall provide Security Administrators the ability to query the currently executing version of the TOE firmware/software and [no other TOE firmware/software version]. Cisco Catalyst 9200L and 9400 Series Switches Page 44 of 67 FPT_TUD_EXT.1.2 The TSF shall provide Security Administrators the ability to manually initiate updates to TOE firmware/software and [no other update mechanism]. FPT_TUD_EXT.1.3 The TSF shall provide a means to authenticate firmware/software updates to the TOE using a [published hash] prior to installing those updates. 5.2.6 TOE Access (FTA) 5.2.6.1 FTA_SSL_EXT.1 TSF-initiated Session Locking FTA_SSL_EXT.1.1 The TSF shall, for local interactive sessions, [ • terminate the session] after a Security Administrator-specified time period of inactivity. 5.2.6.2 FTA_SSL.3 TSF-initiated Termination FTA_SSL.3.1: The TSF shall terminate a remote interactive session after a Security Administrator-configurable time interval of session inactivity. 5.2.6.3 FTA_SSL.4 User-initiated Termination FTA_SSL.4.1 The TSF shall allow Administrator-initiated termination of the Administrator’s own interactive session. 5.2.6.4 FTA_TAB.1 Default TOE Access Banners FTA_TAB.1.1: Before establishing an administrative user session the TSF shall display a Security Administrator-specified advisory notice and consent warning message regarding use of the TOE. 5.2.7 Trusted Path/Channels (FTP) 5.2.7.1 FTP_ITC.1 Inter-TSF trusted channel FTP_ITC.1.1: The TSF shall be capable of using [IPsec] to provide a trusted communication channel between itself and authorized IT entities supporting the following capabilities: audit server, [authentication server] that is logically distinct from other communication channels and provides assured identification of its end points and protection of the channel data from disclosure and detection of modification of the channel data. FTP_ITC.1.2 The TSF shall permit the TSF or the authorized IT entities to initiate communication via the trusted channel. Cisco Catalyst 9200L and 9400 Series Switches Page 45 of 67 FTP_ ITC.1.3 The TSF shall initiate communication via the trusted channel for [communications with the following: • remote AAA servers using IPsec • external audit server using IPsec ]. 5.2.7.2 FTP_TRP.1 Trusted Path FTP_TRP.1.1/Admin: The TSF shall be capable of using [SSH] to provide a communication path between itself and authorized administrators that provides confidentiality and integrity, that is logically distinct from other communication paths and provides assured identification of its end points and protection of the communicated data from disclosure and provides detection of modification of the channel data. FTP_TRP.1.2/Admin The TSF shall permit remote Administrators to initiate communication via the trusted path. FTP_TRP.1.3/Admin The TSF shall require the use of the trusted path for initial Administrator authentication and all remote administration actions. 5.3 TOE SFR Dependencies Rationale for SFRs Found in NDcPPv2.0 The Security Functional Requirements (SFRs) in this Security Target represent the SFRs identified in the NDcPPv2.0e. As such, the NDcPPv2.0e SFR dependency rationale is deemed acceptable since the PP itself has been validated. 5.4 Security Assurance Requirements 5.4.1 SAR Requirements The TOE assurance requirements for this ST are taken directly from the NDcPPv2.0e, which are derived from Common Criteria Version 3.1, Revision 4, dated September 2012. The assurance requirements are summarized in the table below. Cisco Catalyst 9200L and 9400 Series Switches Page 46 of 67 Table 18: Assurance Measures Assurance Class Components Components Description Security Target (ASE) ASE_CCL.1 Conformance claims ASE_ECD.1 Extended components definition ASE_INT.1 ST introduction ASE_OBJ.1 Security objectives for the operational environment ASE_REQ.1 Stated security requirements ASE_SPD.1 Security Problem Definition ASE_TSS.1 TOE summary specification Development (ADV) ADV_FSP.1 Basic Functional Specification Guidance Documents (AGD) AGD_OPE.1 Operational user guidance AGD_PRE.1 Preparative User guidance Life Cycle Support (ALC) ALC_CMC.1 Labeling of the TOE ALC_CMS.1 TOE CM coverage Tests (ATE) ATE_IND.1 Independent testing - conformance Vulnerability Assessment (AVA) AVA_VAN.1 Vulnerability analysis 5.4.2 Security Assurance Requirements Rationale The Security Assurance Requirements (SARs) in this Security Target represent the SARs identified in the NDcPPv2.0e. As such, the NDcPPv2.0e SAR rationale is deemed acceptable since the PP itself has been validated. 5.5 Assurance Measures The TOE satisfies the identified assurance requirements. This section identifies the Assurance Measures applied by Cisco to satisfy the assurance requirements. The table below lists the details. Table 19 Assurance Measures Component How requirement will be met Security Target (ASE) / ASE_CCL.1 / ASE_ECD.1 / ASE_INT.1 / ASE_OBJ.1 / ASE_REQ.1 / ASE_SPD.1 / ASE_TSS.1 Section 2 of this ST includes the TOE and ST conformance claim to CC Version 3.1, Revision 4, dated: September 2012, CC Part 2 extended and CC Part 3 conformant and NDcPPv2.0e and the rationale of how TOE provides all the functionality at a level of security commensurate with that identified in NDcPPv2.0e. Section 2 also includes the consistency rationale for the TOE Security Problem Definition and the Security Requirements to include the extended components definition. Cisco Catalyst 9200L and 9400 Series Switches Page 47 of 67 Component How requirement will be met ADV_FSP.1 The functional specification describes the external interfaces of the TOE; such as the means for a user to invoke a service and the corresponding response of those services. The description includes the interface(s) that enforces a security functional requirement, the interface(s) that supports the enforcement of a security functional requirement, and the interface(s) that does not enforce any security functional requirements. The interfaces are described in terms of their: • purpose (general goal of the interface); • method of use (how the interface is to be used); • parameters (explicit inputs to and outputs from an interface that control the behaviour of that interface); • parameter descriptions (tells what the parameter is in some meaningful way); and • error messages (identifies the condition that generated it, what the message is, and the meaning of any error codes). The development evidence also contains a tracing of the interfaces to the SFRs described in this ST. AGD_OPE.1 The Administrative Guide provides the descriptions of the processes and procedures of how the administrative users of the TOE can securely administer the TOE using the interfaces that provide the features and functions detailed in the ST. AGD_PRE.1 The Installation Guide describes the installation, generation and startup procedures so that the users of the TOE can setup the components of the TOE in the evaluated configuration. ALC_CMC.1 The Configuration Management (CM) document(s) describes how the consumer (end-user) of the TOE can identify the evaluated TOE (Target of Evaluation). The CM document(s) identifies the configuration items, how those configuration items are uniquely identified, and the adequacy of the procedures that are used to control and track changes that are made to the TOE. This includes details on what changes are tracked, how potential changes are incorporated, and the degree to which automation is used to reduce the scope for error. ALC_CMS.1 ATE_IND.1 Cisco will provide the TOE for testing. AVA_VAN.1 Cisco will provide the TOE for testing. Cisco Catalyst 9200L and 9400 Series Switches Page 48 of 67 6 TOE SUMMARY SPECIFICATION 6.1 TOE Security Functional Requirement Measures This chapter identifies and describes how the TOE meets the Security Functional Requirements identified in this document. Table 20 How TOE SFRs Measures TOE SFRs How the SFR is Met FAU_GEN.1 The TOE generates an audit record whenever an audited event occurs. The types of events that cause audit records to be generated include cryptography related events such as, generating keys (e.g. RSA), importing of X509 certificates, and management of the cryptographic algorithms is provided through the CLI with auditing of those commands. Audit records are also generated for identification and authentication related events and administrative events (the specific events and the contents of each audit record are listed in the table within the FAU_GEN.1 SFR, “Auditable Events Table”. Each of the events is specified in the audit record is in enough detail to identify the user for which the event is associated (e.g. user identity, MAC address, IP address), when the event occurred, where the event occurred, the outcome of the event, and the type of event that occurred such as generating keys, including the type of key. Additionally, the startup and shutdown of the audit functionality is audited. The audit trail consists of the individual audit records; one audit record for each event that occurred. The audit record can contain up to 80 characters and a percent sign (%), which follows the time-stamp information. As noted above, the information includes [at least] all of the required information. Additional information can be configured and included if desired. Refer to the Common Criteria Operational User Guidance and Preparative Procedures for command description and usage information. Following is the audit record format: seq no:timestamp: %facility-severity-MNEMONIC:description (hostname-n) Following is an example of an audit record: *Mar 1 18:46:11: %SYS-5-CONFIG_I: Configured from console by vty2 (10.34.195.36) 18:47:02: %SYS-5-CONFIG_I: Configured from console by vty2 (10.34.195.36) *Mar 1 18:48:50.483 UTC: %SYS-5-CONFIG_I: Configured from console by vty2 (10.34.195.36) The logging buffer size can be configured from a range of 4096 (default) to 2147483647 bytes. It is noted, not make the buffer size too large because the switch could run out of memory for other tasks. Use the show memory privileged EXEC command to view the free processor memory on the switch. However, this value is the maximum available, and the buffer size should not be set to this amount. Refer to the Common Criteria Operational User Guidance and Preparative Procedures for command description and usage information. The log buffer is circular, so newer messages overwrite older messages after the buffer is full. Administrators are instructed to monitor the log buffer using the show logging privileged EXEC command to view the audit records. The first message displayed is the oldest message in the buffer. There are other associated commands to Cisco Catalyst 9200L and 9400 Series Switches Page 49 of 67 TOE SFRs How the SFR is Met clear the buffer, to set the logging level, etc., all of which are described in the Guidance documents and IOS CLI. Refer to the Common Criteria Operational User Guidance and Preparative Procedures for command description and usage information. The logs can be saved to flash memory, so records are not lost in case of failures or restarts. Refer to the Common Criteria Operational User Guidance and Preparative Procedures for command description and usage information. The administrator can set the level of the audit records to be displayed on the console or sent to the syslog server. For instance, all emergency, alerts, critical, errors, and warning message can be sent to the console alerting the administrator that some action needs to be taken as these types of messages mean that the functionality of the switch is affected. All notifications and information type message can be sent to the syslog server, whereas message is only for information; switch functionality is not affected. To configure the TOE to send audit records to a syslog server, the ‘set logging server’ command is used. A maximum of three syslog servers can be configured. Refer to the Common Criteria Operational User Guidance and Preparative Procedures for command description and usage information. The audit records are transmitted using IPsec tunnel to the syslog server. If the communications to the syslog server is lost, the TOE generates an audit record and all permit traffic is denied until the communications is re-established. The FIPS crypto tests performed during startup, the messages are displayed only on the console. Once the box is up and operational and the crypto self-test command is entered, then the messages would be displayed on the console and will also be logged. For the TSF self-test, successful completion of the self-test is indicated by reaching the log-on prompt. If there are issues, the applicable audit record is generated and displayed on the console. FAU_GEN.2 The TOE shall ensure that each auditable event is associated with the user that triggered the event and as a result, they are traceable to a specific user. For example, a human user, user identity or related session ID would be included in the audit record. For an IT entity or device, the IP address, MAC address, host name, or other configured identification is presented. Refer to the Common Criteria Operational User Guidance and Preparative Procedures for command description and usage information. FAU_STG_EXT.1 The TOE is configured to export syslog records to a specified, external syslog server. Once the configuration is complete, the audit records are automatically sent to the external syslog server at the same time as they are written to the logging buffer. The TOE protects communications with an external syslog server via IPsec. If the IPsec connection fails, the TOE will store audit records on the TOE when it discovers it can no longer communicate with its configured syslog server. When the connection is restored, the TOE will transmit the buffer contents when connectivity to the syslog server For audit records stored internally to the TOE, the log file is circular; the TOE may overwrite the oldest audit records when the audit trail becomes full. The size of the logging files on the TOE is configurable by the administrator with the minimum value being 4096 (default) to 2147483647 bytes of available disk space. Please refer to the Common Criteria Operational User Guidance and Preparative Procedures for configuration syntax and usage information. Cisco Catalyst 9200L and 9400 Series Switches Page 50 of 67 TOE SFRs How the SFR is Met Only Authorized Administrators are able to clear the local logs, and local audit records are stored in a directory that does not allow administrators to modify the contents. FCS_CKM.1 The TOE implements Diffie-Hellman based key establishment schemes that meets RFC 3526, Section 3. The TOE implements and uses the prime and generator specified in RFC 3526 Section 3 when generating parameters for the key exchange. Asymmetric cryptographic keys used for IKE peer authentication are generated according to FIPS PUB 186-4, Appendix B.3 for RSA schemes. The TOE can create a RSA public-private key pair that can be used to generate a Certificate Signing Request (CSR). Through use of Simple Certificate Enrollment Protocol (SCEP), the TOE can send the CSR to a Certificate Authority (CA) for the CA to generate a certificate and receive its X509v3 certificate from the CA. Integrity of the CSR and certificate during transit are assured through use of digitally signatures (encrypting the hash of the TOE’s public key contained in the CSR and certificate). The TOE can store and distribute the certificate to external entities including Registration Authorities (RA). The key pair generation portions of "The RSA Validation System" for FIPS 186-4 were used as a guide in testing the FCS_CKM.1 during the FIPS validation. The TOE implements Diffie-Hellman (DH) group 14 (2048) bit key generation schemes in SSH. The DH key generation meets RFC3526, Section 3. The TOE acts as a receiver for SSH communications and as both a sender and receiver for IPsec communications. For details on each protocol, see the related SFR. FCS_CKM.2 FCS_CKM.4 The TOE meets all requirements specified in FIPS 140-2 for destruction of keys and Critical Security Parameters (CSPs) when no longer required for use. See Table 21: TOE Key Zeroization in Section 7 Annex A: Key Zeroization, 7.1 Key Zeroization The information provided in the table includes all of the all secrets, keys and associated values, the description, and the method used to zeroization when no longer required for use. The information is provided in the reference section for ease and readability of all of the all secrets, keys and associated values, their description and zeroization methods. FCS_COP.1/DataEncryption The TOE provides symmetric encryption and decryption capabilities using AES in CBC mode (128, 256 bits) as described in ISO 18033-3 and ISO 10116. AES is implemented in the following protocols: IPsec and SSH. The relevant FIPS certificate numbers are listed in Table 6 FIPS References. FCS_COP.1SigGen The TOE provides cryptographic signature services using RSA Digital Signature Algorithm with key size of 2048 and greater as specified in FIPS PUB 186-4, “Digital Signature Standard”. The relevant FIPS certificate numbers are listed in Table 6 FIPS References. Cisco Catalyst 9200L and 9400 Series Switches Page 51 of 67 TOE SFRs How the SFR is Met FCS_COP.1Hash The TOE provides cryptographic hashing services using SHA-1, SHA-256 and SHA- 512 as specified in ISO/IEC 10118-3:2004 (with key sizes and message digest sizes of 160, 256, and 512 bits respectively). The TOE provides keyed-hashing message authentication services using HMAC- SHA-1 and HMAC-SHA-256 that operates on 512-bit blocks and HMAC-SHA-512 operating on 1024-bit blocks of data, with key sizes and message digest sizes of 160- bits, 256 bits and 512 bits respectively as specified in ISO/IEC 9797-2:2011, Section 7 “MAC Algorithm 2”. For IKE (ISAKMP) hashing, administrators can select any of SHA-1, SHA-256 and/or SHA-512 (with message digest sizes of 160, 256 and 512 bits respectively) to be used with remote IPsec endpoints. SHA-512 hashing is used for verification of software image integrity. The TOE uses HMAC-SHA1 message authentication as part of the RADIUS Key Wrap functionality. For IPsec SA authentication integrity options administrators can select any of esp-sha- hmac (HMAC-SHA-1), esp-sha256-hmac, or esp-sha512-hmac (with message digest sizes of 160 and 256 and 512 bits respectively) to be part of the IPsec SA transform- set to be used with remote IPsec endpoints. The relevant FIPS certificate numbers are listed in Table 6 FIPS References. The configuration steps, commands and algorithms for the supported keys, key sizes and hashing are provided in the Operational User Guidance And Preparative Procedures. FCS_COP.1/KeyedHash FCS_IPSEC_EXT.1 The IPsec implementation provides both VPN peer-to-peer and VPN client to TOE capabilities. The VPN peer-to-peer tunnel allows for example the TOE and another switch to establish an IPsec tunnel to secure the passing of route tables (user data). Another configuration in the peer-to-peer configuration is to have the TOE be set up with an IPsec tunnel with a VPN peer to secure the session between the TOE and syslog server. The VPN client to TOE configuration would be where a remote VPN client connects into the TOE in order to gain access to an authorized private network. Authenticating with the TOE would give the VPN client a secure IPsec tunnel to connect over the internet into their private network. In addition to tunnel mode, which is the default IPsec mode, the TOE also supports transport mode, allowing for only the payload of the packet to be encrypted. If tunnel mode is explicitly specified, the switch will request tunnel mode and will accept only tunnel mode. The TOE implements IPsec to provide both certificates and pre-shared key-based authentication and encryption services to prevent unauthorized viewing or modification of data as it travels over the external network. The TOE implementation of the IPsec standard (in accordance with the RFCs noted in the SFR) uses the Encapsulating Security Payload (ESP) protocol to provide authentication, encryption and anti-replay services. The IPsec protocol ESP is implemented using the cryptographic algorithms AES-CBC-128 and AES-CBC-256 together with HMAC- SHA-1, HMAC-SHA-256 and HMAC-SHA-512. Cisco Catalyst 9200L and 9400 Series Switches Page 52 of 67 TOE SFRs How the SFR is Met Preshared keys can be configured using the 'crypto isakmp key' key command and may be proposed by each of the peers negotiating the IKE establishment. IPsec Internet Key Exchange, also called ISAKMP, is the negotiation protocol that lets two peers agree on how to build an IPsec Security Association (SA). The IKE protocols implement Peer Authentication using the RSA algorithm with X.509v3 certificates or preshared keys. When certificates are used for authentication, the distinguished name (DN) is verified to ensure the certificate is valid and is from a valid entity. The DN naming attributes in the certificate is compared with the expected DN naming attributes and deemed valid if the attribute types are the same and the values are the same and as expected. The fully qualified domain name (FQDN) can also be used as verification where the attributes in the certificate are compared with the expected FQDN. IKE separates negotiation into two phases: phase 1 and phase 2. Phase 1 creates the first tunnel, which protects later ISAKMP negotiation messages. The key negotiated in phase 1 enables IKE peers to communicate securely in phase 2. During Phase 2 IKE establishes the IPsec SA. IKE maintains a trusted channel, referred to as a Security Association (SA), between IPsec peers that is also used to manage IPsec connections, including: • The negotiation of mutually acceptable IPsec options between peers (including peer authentication parameters, either signature based, or pre-shared key based), • The establishment of additional Security Associations to protect packets flows using Encapsulating Security Payload (ESP), and • The agreement of secure bulk data encryption AES keys for use with ESP. After the two peers agree upon a policy, the security parameters of the policy are identified by an SA established at each peer, and the IKE SAs apply to all subsequent IKE traffic during the negotiation. The TOE supports both IKEv1 and IKEv2 session establishment. As part of this support, the TOE can be configured to not support aggressive mode for IKEv1 exchanges and to only use main mode using the 'crypto isakmp aggressive-mode disable' command. The TOE can be configured to not allow "confidentiality only" ESP mode by ensuring the IKE Policies configured include ESP-encryption. The TOE supports configuration lifetimes of both Phase 1 SAs and Phase 2 SAs using "lifetime" command. The default time value for Phase 1 SAs is 24 hours, though is configurable from 1 to 24 hours. The default time value for Phase 2 SAs is 1 hour, though is configurable up to 8 hours. The TOE also supports configuring the maximum amount of traffic that is allowed to flow for a given IPsec SA using the following command, 'crypto ipsec security- association lifetime'. The default amount is 2560KB, which is the minimum configurable value. The maximum configurable value is 4GB. The TOE provides AES-CBC-128 and AES-CBC-256 for encrypting the IKEv1 and IKEv2 payloads. The administrator is instructed in the AGD to ensure that the size of key used for ESP must be greater than or equal to the key size used to protect the IKE payload. Cisco Catalyst 9200L and 9400 Series Switches Page 53 of 67 TOE SFRs How the SFR is Met The TOE supports Diffie-Hellman Group 14 (2048-bit keys), in support of IKE Key Establishment. These keys are generated using the AES-CTR Deterministic Random Bit Generator (DRBG), as specified in SP 800-90, and the following corresponding key sizes (in bits) are used: 320 (for DH Group 14) bits. The DH group can be configured by issuing the following command during the configuration of IPsec: TOE-common-criteria (config-isakmp)# group 14 This selects DH Group 14 (2048-bit MODP) for IKE and this sets the DH group offered during negotiations. The TOE generates the secret value 'x' used in the IKEv1 and IKEv2 Diffie-Hellman key exchange ('x' in gx mod p) using the NIST approved AES-CTR Deterministic Random Bit Generator (DRBG) specified in FCS_RBG_EXT.1 and having possible lengths of 320 bits. When a random number is needed for a nonce, the probability that a specific nonce value will be repeated during the life a specific IPsec SA is less than 1 in 2^128. The nonce is likewise generated using the AES-CTR DRBG. IPsec provides secure tunnels between two peers, such as two switches and remote VPN clients. An authorized administrator defines which packets are considered sensitive and should be sent through these secure tunnels. When the IPsec peer recognizes a sensitive packet, the peer sets up the appropriate secure tunnel and sends the packet through the tunnel to the remote peer. More accurately, these tunnels are sets of security associations (SAs) that are established between two IPsec peers or between the TOE and remote VPN client. The SAs define the protocols and algorithms to be applied to sensitive packets and specify the keying material to be used. SAs are unidirectional and are established per security protocol (AH or ESP). In the evaluated configuration, only ESP will be configured for use. A crypto map (the Security Policy Definition (SPD)) set can contain multiple entries, each with a different access list. The crypto map entries are searched in a sequence - the switch attempts to match the packet to the access list (acl) specified in that entry. When a packet matches a permit entry in a particular access list, the method of security in the corresponding crypto map is applied. If the crypto map entry is tagged as ipsecisakmp, IPsec is triggered. The traffic matching the permit acls would then flow through the IPsec tunnel and be classified as "PROTECTED". Traffic that does not match a permit crypto map acl and does not match a non-crypto permit acl on the interface would be DISCARDED. Traffic that does not match a permit acl in the crypto map but does match a non-crypto permit acl would be allowed to BYPASS the tunnel. For example, a non-crypto permit acl for icmp would allow ping traffic to flow unencrypted if a permit crypto map was not configured that matches the ping traffic. The TOE implementation of the IPsec standard (in accordance with the RFCs noted in the SFR and using cryptographic algorithms AES-CBC-128 and AES-CBC-256 together with HMAC-SHA1, HMAC-SHA-256, and HMAC-SHA-512) uses the Encapsulating Security Payload (ESP) protocol to provide authentication, encryption and anti-replay services. If there is no SA that the IPsec can use to protect this traffic to the peer, IPsec uses IKE to negotiate with the remote peer to set up the necessary IPsec SAs on behalf of the data flow. The negotiation uses information specified in the crypto map entry as well as the data flow information from the specific access list entry. Cisco Catalyst 9200L and 9400 Series Switches Page 54 of 67 TOE SFRs How the SFR is Met In IOS-XE the negotiations of the IKE SA, adheres to configuration settings for IPsec applied by the administrator. For example, in the first SA, the encryption, hash and DH group is identified, for the Child SA the encryption and the hash are identified. The administrator configures the first SA to be as strong as or stronger than the child SA; meaning if the first SA is set at AES 128, then the Child SA can only be AES128. If the first SA is AES256, then the Child SA could be AES128 or AES256. During the negotiations, if a non-match is encountered, the process stops, and an error message is received. FCS_SSHS_EXT.1 The TOE implementation of SSHv2 supports the following: • Compliance with RFCs 4251, 4252, 4253, and 4254; • Dropping packets greater than 65,535 bytes, as such packets would violate the IP packet size limitations; • Enforcement to only allow the encryption algorithms AES-CBC-128, and AES-CBC-256 to ensure confidentiality of the session; • Enforcement to only use of the SSH_RSA public key algorithms for authentication; • Password-based authentication; • Enforcement to only allow the hashing algorithms hmac-sha1 and hmac- sha1-96 to ensure the integrity of the session and • Enforcement of DH Group 14 (diffie-hellman-group-14-sha1) as defined by the NDcPPv2.0e. The TOE can also be configured to ensure that SSH re-key of no longer than one hour and no more than one gigabyte of transmitted data for the session key. FCS_RBG_EXT.1 The TOE implements a NIST-approved AES-CTR Deterministic Random Bit Generator (DRBG), as specified in SP 800-90 seeded by an entropy source that accumulates entropy from a TSF-hardware based noise source. The deterministic RBG is seeded with a minimum of 256 bits of entropy, which is at least equal to the greatest security strength of the keys and hashes that it will generate. FIA_AFL.1 The TOE provides the privileged administrator the ability to specify the maximum number of unsuccessful authentication attempts before privileged administrator or non-privileged administrator is locked out through the administrative CLI using a privileged CLI command. While the TOE supports a range from 1-25, in the evaluated configuration, the maximum number of failed attempts is recommended to be set to 3. When a privileged administrator or non-privileged administrator attempting to log into the administrative CLI reaches the administratively set maximum number of failed authentication attempts, the user will not be granted access to the administrative functionality of the TOE until a privileged administrator resets the user's number of failed login attempts through the administrative CLI. To ensure the privileged administrator account does not get locked out by the number of failed attempts it is essential that an additional Administrator account be created to only be used in an emergency at the local console to unlock the locked Administrator account. Although, it is noted that the lockout is not applicable to the local console administrators. FIA_PMG_EXT.1 The TOE supports the local definition of users with corresponding passwords. The passwords can be composed of any combination of upper and lower case letters, Cisco Catalyst 9200L and 9400 Series Switches Page 55 of 67 TOE SFRs How the SFR is Met numbers, and special characters (that include: [“!”, “@”, “#”, “$”, “%”, “^”, “&”, “*”, “(“,”)” Minimum password length is settable by the Authorized Administrator, and can be configured for minimum password lengths of 15 characters. FIA_UIA_EXT.1 The TOE requires all users to be successfully identified and authenticated before allowing any TSF mediated actions to be performed except for the login warning banner that is displayed prior to user authentication. Administrative access to the TOE is facilitated through the TOE’s CLI. The TOE mediates all administrative actions through the CLI. Once a potential administrative user attempts to access the CLI of the TOE through either a directly connected console or remotely through an SSHv2 secured connection, the TOE prompts the user for a user name and password. Only after the administrative user presents the correct authentication credentials will access to the TOE administrative functionality be granted. No access is allowed to the administrative functionality of the TOE until an administrator is successfully identified and authenticated. The TOE provides a local password-based authentication mechanism as well as RADIUS AAA server for remote authentication. The administrator authentication policies include authentication to the local user database or redirection to a remote authentication server. Interfaces can be configured to try one or more remote authentication servers, and then fail back to the local user database if the remote authentication servers are inaccessible. The process for authentication is the same for administrative access whether administration is occurring via a directly connected local console or remotely via SSHv2 secured connection. At initial login, the administrative user is prompted to provide a username. After the user provides the username, the user is prompted to provide the administrative password associated with the user account. The TOE then either grant administrative access (if the combination of username and password is correct) or indicate that the login was unsuccessful. The TOE does not provide a reason for failure in the cases of a login failure. FIA_UAU_EXT.2 FIA_UAU.7 When a user enters their password at the directly connected local console, the TOE displays only ‘*’ characters so that the user password is obscured. For remote session authentication via SSHv2 secured connection, the TOE does not echo any characters as they are entered. FIA_X509_EXT.1/Rev The TOE uses X.509v3 certificates as defined by RFC 5280 to support authentication for IPsec connections. The Certificate Authority (CA) server in the IT Environment acts as an OCSP server and/or as a CRL distribution point. The TOE supports the following methods to obtain a certificate from a CA: • Simple Certificate Enrollment Protocol (SCEP)—A Cisco-developed enrollment protocol that uses HTTP to communicate with the CA or registration authority (RA). • Imports certificates in PKCS12 format from an external server FIA_X509_EXT.2 FIA_X509_EXT.3 Cisco Catalyst 9200L and 9400 Series Switches Page 56 of 67 TOE SFRs How the SFR is Met • IOS-XE File System (IFS)—The switch uses any file system that is supported by Cisco IOS-XE software (such as TFTP, FTP, flash, and NVRAM) to send a certificate request and to receive the issued certificate. • Manual cut-and-paste—The switch displays the certificate request on the console terminal, allowing the administrator to enter the issued certificate on the console terminal; manually cut-and-paste certificate requests and certificates when there is no network connection between the switch and CA • Enrollment profiles—The switch sends HTTP-based enrollment requests directly to the CA server instead of to the RA-mode certificate server (CS). • Self-signed certificate enrollment for a trust point When the CA issues a certificate, the CA can include in the certificate the CRL distribution point (CDP) for that certificate. The TOE will use the CDPs to locate and load the correct CRL. If a CDP is not specified in the certificate, the TOE will use the default Simple Certificate Enrollment Protocol (SCEP) method to retrieve the CRL. For OCSP, the OCSP server provides real-time certificate status checking. The OCSP server validation is based on the root CA certificate or a valid subordinate CA certificate. All of the certificates include at least the following information: public key, Common Name, Organization, Organizational Unit and Country. Public key infrastructure (PKI) credentials, such as Rivest, Shamir, and Adelman (RSA) keys and certificates can be stored in a specific location on the TOE. Certificates are stored to NVRAM by default; however, some switches do not have the required amount of NVRAM to successfully store certificates. All Cisco platforms support NVRAM and flash local storage. Depending on the platform, an authorized administrator may have other supported local storage options including bootflash, slot, disk, USB flash, or USB token. During run time, an authorized administrator can specify what active local storage device will be used to store certificates. The certificates themselves provide protection in that they are digitally signed. If a certificate were modified in any way, it would be invalidated. The digital signature verifications process would show that the certificate had been tampered with when the hash value would be invalid. The certificate chain establishes a sequence of trusted certificates, from a peer certificate to the root CA certificate. Within the PKI hierarchy, all enrolled peers can validate the certificate of one another if the peers share a trusted root CA certificate or a common subordinate CA. Each CA corresponds to a trust point. When a certificate chain is received from a peer, the default processing of a certificate chain path continues until the first trusted certificate, or trust point, is reached. The administrator may configure the level to which a certificate chain is processed on all certificates including subordinate CA certificates. To verify, the authorized administrator could ‘show’ the pki certificates and the pki trust points. The authorized administrator can also configure one or more certificate fields together with their matching criteria to match. Such as: • alt-subject-name • expires-on Cisco Catalyst 9200L and 9400 Series Switches Page 57 of 67 TOE SFRs How the SFR is Met • issuer-name • name • serial-number • subject-name • unstructured-subject-name • valid-start This allows for installing more than one certificate from one or more CAs on the TOE. For example, one certificate from one CA could be used for one IPsec connection, while another certificate from another CA could be used for a different IPsec connection. However, the default configuration is a single certificate from one CA that is used for all authenticated connections. The physical security of the TOE (A.PHYSICAL_PROTECTION) protects the switch and the certificates from being tampered with or deleted. Only authorized administrators with the necessary privilege level can access the certificate storage and add/delete them. In addition, the TOE identification and authentication security functions protect an unauthorized user from gaining access to the TOE. USB tokens provide for secure configuration distribution of the digital certificates and private keys. RSA operations such as on-token key generation, signing, and authentication, and the storage of Virtual Private Network (VPN) credentials for deployment can be implemented using the USB tokens. The use of CRL and OCSP is configurable and may be used for certificate revocation. The authorized administrator uses the revocation-check command to specify at least one method of revocation checking; CRL is the default method, though OCSP may also be used. The authorized administer sets the trust point and its name and the revocation-check method • crl --Certificate checking is performed by a CRL. This is the default option. • ocsp --Certificate checking is performed by an OCSP server There is also an option of ‘none’, where certificate checking is ignored, however this cannot be selected in the evaluated configuration. Checking is also done for the basicConstraints extension and the CA flag to determine whether they are present and set to TRUE. The local certificate that was imported must contain the basic constraints extension with the CA flag set to true, the check also ensure that the key usage extension is present, and the keyEncipherment bit or the keyAgreement bit or both are set. If they are not, the certificate is not accepted. If the connection to determine the certificate validity cannot be established, the TOE rejects the certificate. FMT_MOF.1/ManualUpdate The TOE performs role-based authorization, using TOE platform authorization mechanisms, to grant access to the privileged and semi-privileged levels. For the purposes of this evaluation, the privileged level is equivalent to full administrative access to the CLI, which is the default access for IOS privilege level 15; and the semi- privileged level equates to any privilege level that has a subset of the privileges assigned to level 15. Privilege levels 0 and 1 are defined by default and are customizable, while levels 2-14 are undefined by default and are also customizable. The term “Authorized Administrator” is used in this ST to refer to any user that has been assigned to a privilege level that is permitted to perform the relevant action; and FMT_MTD.1/CoreData FMT_MTD.1/CryptoKeys Cisco Catalyst 9200L and 9400 Series Switches Page 58 of 67 TOE SFRs How the SFR is Met therefore, has the appropriate privileges to perform the requested functions. As such the semi-privileged administrators with only a subset of privileges may also manage and modify TOE data based on the privileges assigned. The TOE provides the ability for Security Administrators (a.k.a Authorized Administrators) to access TOE data, such as audit data, configuration data, security attributes, session thresholds, cryptographic keys and updates. Each of the predefined and administratively configured privilege level has a set of permissions that will grant them access to the TOE data, though with some privilege levels, the access is limited. The TOE does not provide automatic updates to the software version running on the TOE. The Security Administrators (a.k.a Authorized Administrators) can query the software version running on the TOE, and can initiate updates to (replacements of) software images. When software updates are made available by Cisco, the Authorized Administrators can obtain, verify the integrity of, and install those updates. The warning and access banner may also be displayed prior to the identification and authentication of an Authorized Administrator. No administrative functionality is available prior to administrative successful login. FMT_SMF.1 The TOE provides all the capabilities necessary to securely manage the TOE. The Security Administrators (a.k.a Authorized Administrators) user can connect to the TOE using the CLI to perform these functions via SSHv2 secured connection, a terminal server, or at the local console. The specific management capabilities available from the TOE include; • Local and remote administration of the TOE and the services provided by the TOE via the TOE CLI, as described above; • The ability to manage the warning banner message and content which allows the Authorized Administrator the ability to define warning banner that is displayed prior to establishing a session (note this applies to the interactive (human) users; e.g. administrative users; • The ability to update the IOS XE software. The validity of the image is provided using SHA-512 published hash prior to installing the update; • The ability to manage the time limits of session inactivity which allows the Authorized Administrator the ability to set and modify the inactivity time threshold; • The ability to manage termination of a local session due to exceeding the threshold of authentication failure attempts. The account is locked until the Authorized Administrator unlocks the account; • The ability to manage audit behavior and the audit logs which allows the Authorized Administrator to view the audit logs and to clear the audit logs; • The ability to manage the cryptographic functionality which allows the Authorized Administrator the ability to identify and configure the algorithms used to provide protection of the data, such as generating the RSA keys to enable SSHv2 and to configure thresholds for SSH rekeying; • The ability to configure the IPsec functionality which supports the secure connections to the audit server and the remote authentication server; • The ability to import the X.509v3 certificates and validate for use in authentication and secure connections, Cisco Catalyst 9200L and 9400 Series Switches Page 59 of 67 TOE SFRs How the SFR is Met • The ability to configure and set the time clock and • The ability to configure the reference identifiers for peers, which can be IP address, FQDN identifier or can be the same as the peer’s name. FMT_SMR.2 The TOE maintains Authorizer Administrators that include privileged and semi- privileged administrator roles to administer the TOE locally and remotely. The TOE performs role-based authorization, using TOE platform authorization mechanisms, to grant access to the privileged and semi-privileged roles. For the purposes of this evaluation, the privileged role is equivalent to full administrative access to the CLI, which is the default access for IOS privilege level 15; and the semi- privileged role equates to any privilege level that has a subset of the privileges assigned to level 15. Privilege levels 0 and 1 are defined by default and are customizable, while levels 2-14 are undefined by default and also customizable. Note: the levels are not theoretically hierarchical. The term “Authorized Administrator” is used in this ST to refer to any user that has been assigned to a privilege level that is permitted to perform the relevant action; and therefore, has the appropriate privileges to perform the requested functions. The privilege level determines the functions the user can perform; hence the Authorized Administrator with the appropriate privileges. The TOE can and shall be configured to authenticate all access to the command line interface using a username and password. The TOE supports both local administration via a directly connected console cable and remote authentication via SSHv2 secure connection. FPT_SKP_EXT.1 The TOE includes CLI command features that can be used to configure the TOE to encrypt all locally defined user passwords. In this manner, the TOE ensures that plaintext user passwords will not be disclosed even to administrators. The command is the password encryption aes command used in global configuration mode. The command service password-encryption applies encryption to all passwords, including username passwords, authentication key passwords, the privileged command password, console and virtual terminal line access passwords. During the setup and configuration of the TOE and the generation of keys, the TOE stores all private keys in a secure directory that is not readily accessible to administrators; hence no interface access. Additionally, all pre-shared and symmetric keys are stored in encrypted form to prevent access. Refer to the Common Criteria Operational User Guidance and Preparative Procedures for command description and usage information. FPT_APW_EXT.1 FPT_STM.1 The TOE provides a source of date and time information used in audit event timestamps. The clock function is reliant on the system clock provided by the underlying hardware. This date and time is used as the time stamp that is applied to TOE generated audit records and used to track inactivity of administrative sessions. Cisco Catalyst 9200L and 9400 Series Switches Page 60 of 67 TOE SFRs How the SFR is Met This system clock is also used for cryptographic functions such as SA lifetimes that are configured based on length of time values configured within 1-24 hours and for certificate validity. FPT_TUD_EXT.1 Authorized Administrator can query the software version running on the TOE and can initiate updates to (replacements of) software images. The software version information for the TOE specific image can be displayed using the following commands. The administrator in privileged EXEC mode enters: Switch# show version (this displays information about the Cisco IOS software version running on the TOE the ROM Monitor and Bootflash software versions, and the hardware configuration, including the amount of system memory When updates are made available by Cisco, an Authorized Administrator can obtain and install those updates. The Authorized Administrator can download the approved image file from Cisco.com onto a trusted computer system for usage in the trusted update functionality. Software images are available from Cisco.com at the following: https://www.cisco.com/cisco/web/download/index.html. Published hash mechanisms are used to verify software/firmware update files (to ensure they have not been modified from the originals distributed by Cisco) before they are used to actually update the TOE. Once the Authorized Administrator has verified the TOE image, the Authorized Administrator can install the file on the TOE after they have logged in and have been successfully identified and authenticated. Once the image is loaded into bootflash, the Authorized Administrator can display information related to software authenticity for a specific image file, using the verify command. For example: <9400># verify FileName: cat9k_iosxe.16.09.02.SPA.bin SHA512 Checksum: fe23adf9ca2f9523620766c5f72b 3944656ddc8b1c5f78257212b71 e0293ff92c4983ac4a85de22de91 26d866f44fcf221e396ae80d0749 876e0a841bb54189e The image name and hash can be verified on the [TOE] download page on Cisco.com (,https://software.cisco.com/download/home/286313983/type/282046477/release/Fuji- 16.9.2). If the there is an issue with the verification of the SHA512 checksum, the software should not be installed and contact Cisco for assistance. Once the Authorized Administrator has verified the TOE image, the file can be installed. Cisco Catalyst 9200L and 9400 Series Switches Page 61 of 67 TOE SFRs How the SFR is Met For full details, refer to the Cisco Catalyst 9200L and 9400 Series Switches running IOS 16.9 Common Criteria Operational User Guidance And Preparative Procedures for assistance. FPT_TST_EXT.1 During the system bootup process (power on or reboot), all the Power on Startup Test (POST) components for all the cryptographic modules perform the POST for the corresponding component (hardware or software). Also, during the initialization and self-tests, the module inhibits all access to the cryptographic algorithms. Additionally, the power-on self-tests are performed after the cryptographic systems are initialized but prior to the underlying OS initialization of external interfaces; this prevents the security appliances from passing any data before completing self-tests and entering FIPS mode. In the event of a power-on self-test failure, the cryptographic module will force the IOS platform to reload and reinitialize the operating system and cryptographic module. This operation ensures no cryptographic algorithms can be accessed unless all power on self-tests are successful. The tests include: • AES Known Answer Test - For the encrypt test, a known key is used to encrypt a known plain text value resulting in an encrypted value. This encrypted value is compared to a known encrypted value to ensure that the encrypt operation is working correctly. The decrypt test is just the opposite. In this test a known key is used to decrypt a known encrypted value. The resulting plaintext value is compared to a known plaintext value to ensure that the decrypt operation is working correctly. • HMAC Known Answer Test - For each of the hash values listed (SHA-1/256/512), the HMAC implementation is fed known plaintext data and a known key. These values are used to generate a MAC. This MAC is compared to a known MAC to verify that the HMAC and hash operations are operating correctly. • RNG/DRBG Known Answer Test - For this test, known seed values are provided to the DRBG implementation. The DRBG uses these values to generate random bits. These random bits are compared to known random bits to ensure that the DRBG is operating correctly. • RSA Signature Known Answer Test (both signature/verification) - This test takes a known plaintext value and Private/Public key pair and used the public key to encrypt the data. This value is compared to a known encrypted value to verify that encrypt operation is working properly. The encrypted data is then decrypted using the private key. This value is compared to the original plaintext value to ensure the decrypt operation is working properly. • SHA-1/256/512 Known Answer Test - For each of the values listed, the SHA implementation is fed known data and key. These values are used to generate a hash. This hash is compared to a known value to verify they match and the hash operations are operating correctly. Cisco Catalyst 9200L and 9400 Series Switches Page 62 of 67 TOE SFRs How the SFR is Met Prior to installing the image, the Authorized Administrator can verify the public hash to ensure the files has not been tampered with prior to installing. In addition, the Software Self-Integrity Test is run automatically whenever the IOS system images is loaded and confirms that the image file that's about to be loaded has maintained its integrity. If any self-tests fail, the TOE transitions into an error state. In the error state, all secure data transmission is halted and the TOE outputs status information indicating the failure. If an error occurs during the self-test, a SELF_TEST_FAILURE system log is generated. Following is an example: Example Error Message _FIPS-2-SELF_TEST_IOS_FAILURE: "IOS crypto FIPS self test failed at %s." Explanation FIPS self test on IOS crypto routine failed. These tests are sufficient to verify that the correct version of the TOE software is running as well as that the cryptographic operations are all performing as expected because any deviation in the TSF behaviour will be identified by the failure of a self- test. FTA_SSL_EXT.1 An Authorized Administrator can configure maximum inactivity times individually for both local and remote administrative sessions through the use of the “session- timeout” setting applied to the directly connected local console and virtual terminal (vty) lines for the remote SSHv2 secure connection. The configuration of the vty lines sets the configuration for the remote SSHv2 secure connection console access. The line console settings that is for the directly connected console, are not immediately activated for the current session. The current line console session must be exited. When the user logs back in, the inactivity timer will be activated for the new session. If a local user session is inactive for a configured period of time, the session will be terminated and will require re-identification and authentication to login. If a remote user session that is for the remote SSHv2 secure connection, is inactive for a configured period of time, the session will be terminated and will require re-identification and authentication to establish a new session. Administratively configurable timeouts are also available for the EXEC level access (access above level 1) through use of the “exec-timeout” setting. The allowable inactivity timeout range is from 1 to 65535 seconds. FTA_SSL.3 FTA_SSL.4 An Authorized Administrator is able to exit out of both local and remote administrative sessions by issuing the ‘exit’ command. FTA_TAB.1 Authorized administrators define a custom login banner that will be displayed at the CLI for both local and remote access configurations prior to allowing Authorized Administrator access through those interfaces. A local console includes any IT Environment Console that is directly connected to the TOE via the Serial Console Port and is used by the TOE administrator to support TOE administration. Whereas a remote console is one that includes any IT Environment Cisco Catalyst 9200L and 9400 Series Switches Page 63 of 67 TOE SFRs How the SFR is Met Management workstation with a SSH client installed that is used by the TOE administrator to support TOE administration through SSH protected channels. Any SSH client that supports SSHv2 may be used. FTP_ITC.1 The TOE protects communications with authorized IT entities such as the remote audit server and remote authentication servers with IPsec. This protects the data from disclosure by encryption and by checksums that verify that data has not been modified. The TOE protects communications with peer or neighbour switches using keyed hash as defined in FCS_COP.1.1(4) and cryptographic hashing functions FCS_COP.1.1(3). This protects the data from modification of data by hashing that verify that data has not been modified in transit. In addition, encryption of the data as defined in FCS_COP.1.1(1) is provided to ensure the data is not disclosed in transit. The TSF allows the TSF, or the authorized IT entities to initiate communication via the trusted channel. FTP_TRP.1/Admin All remote administrative communications take place over a secure encrypted SSHv2 session. The SSHv2 session is encrypted using AES encryption. The remote users (Authorized Administrators) are able to initiate SSHv2 communications with the TOE. Cisco Catalyst 9200L and 9400 Series Switches Page 64 of 67 7 ANNEX A: KEY ZEROIZATION 7.1 Key Zeroization The following table describes the key zeroization referenced by FCS_CKM.4 provided by the TOE. As described below in the table, the TOE zeroize all secrets, keys and associated values when they are no longer required. Using the commands, no crypto isakmp key, crypto key zeroize rsa or no radius-server key will zeroized all said keys. The process in which the TOE zeroizes, meets FIPS 140 validation. Table 21: TOE Key Zeroization Name Description Zeroization Diffie-Hellman Shared Secret The value is zeroized after it has been given back to the consuming operation. The value is overwritten by 0’s. This key is stored in DRAM. Automatically after completion of DH exchange. Overwritten with a single overwrite consisting of zeros Diffie Hellman private exponent This is the private exponent used as part of the Diffie-Hellman key exchange. This key is stored in DRAM. Zeroized upon completion of DH exchange. Overwritten with a single overwrite consisting of zeros skeyid This is an IKE intermittent value used to create skeyid_d. This information is stored in DRAM. This information and keys are stored in DRAM. Automatically after IKE session terminated. Overwritten with a single overwrite consisting of zeros skeyid_d This is an IKE intermittent value used to derive keying data for IPsec. This information and keys are stored in DRAM. Automatically after IKE session terminated. Overwritten with a single overwrite consisting of zeros IKE session encrypt key This the key IPsec key used for encrypting the traffic in an IPsec connection. This key is stored in DRAM. Automatically after IKE session terminated. Overwritten with a single overwrite consisting of zeros IKE session authentication key This the key IPsec key used for authenticating the traffic in an IPsec connection. This key is stored in DRAM. Automatically after IKE session terminated. Overwritten with a single overwrite consisting of zeros Cisco Catalyst 9200L and 9400 Series Switches Page 65 of 67 Name Description Zeroization ISAKMP preshared This is the configured pre-shared key for ISAKMP negotiation. This key is stored in NVRAM. Zeroized using the following command: # no crypto isakmp key Overwritten with a single overwrite consisting of zeros IKE RSA Private Key The RSA private-public key pair is created by the device itself using the key generation CLI described below. The device’s public key must be added into the device certificate. The device’s certificate is created by creating a trustpoint on the device. This trustpoint authenticates with the CA server to get the CA certificate and to enrol with the CA server to generate the device certificate. In the IKE authentication step, the device’s certificate is first sent to other device so that it can be authenticated. The other device verifies the certificate is signed by CA’s signing key, and then the device sends a random secret encrypted by the device’s public key in the valid device certificate. Thus establishing the trusted connection since only the device with the matching device private key can decrypt the message and obtain the random secret. This key is stored in NVRAM. Zeroized using the following command: # crypto key zeroize rsa1 Overwritten with a single overwrite consisting of zeros IPsec encryption key This is the key used to encrypt IPsec sessions. This key is stored in DRAM. Automatically when IPsec session terminated. Overwritten with a single overwrite consisting of zeros IPsec authentication key This is the key used to authenticate IPsec sessions. This key is stored in DRAM. Automatically when IPsec session terminated. Overwritten with a single overwrite consisting of zeros RADIUS secret Shared secret used as part of the Radius authentication method. The password is stored in NVRAM. Zeroized using the following command: # no radius-server key Overwritten with a single overwrite consisting of zeros 1 Issuing this command will zeroize/delete all RSA keys on the TOE Cisco Catalyst 9200L and 9400 Series Switches Page 66 of 67 Name Description Zeroization SSH Private Key This is the private (secret) key of the asymmetric key pair required to establish the secure SSH session. The key is stored in NVRAM. Zeroized using the following command: # crypto key zeroize rsa2 Overwritten with a single overwrite consisting of zeros SSH Session Key Once the function has completed the operations requiring the RSA key object, the module over writes the entire object (no matter its contents). This key is stored in DRAM. Automatically when the SSH session is terminated. Overwritten with a single overwrite consisting of zeros User Password This is a variable 15+-character password that is used to authenticate local users. The password is stored in NVRAM. Zeroized by overwriting with new password Enable Password (if used) This is a variable 15+-character password that is used to authenticate local users at a higher privilege level. The password is stored in NVRAM. Zeroized by overwriting with new password RNG Seed This seed is for the RNG. The seed is stored in DRAM. Zeroized upon power cycle the device RNG Seed Key This is the seed key for the RNG. The seed key is stored in DRAM. Zeroized upon power cycle the device 2 Issuing this command will zeroize/delete all RSA keys on the TOE Cisco Catalyst 9200L and 9400 Series Switches Page 67 of 67 8 ANNEX B: REFERENCES The following documentation was used to prepare this ST: Table 22: References Identifier Description [CC_PART1] Common Criteria for Information Technology Security Evaluation – Part 1: Introduction and general model, Version 3.1, Revision 4, dated: September 2012 [CC_PART2] Common Criteria for Information Technology Security Evaluation – Part 2: Security functional components, Version 3.1, Revision 4, dated: September 2012 [CC_PART3] Common Criteria for Information Technology Security Evaluation – Part 3: Security assurance components, Version 3.1, Revision 4, dated: September 2012 [CEM] Common Methodology for Information Technology Security Evaluation – Evaluation Methodology, Version 3.1, Revision 4, dated: September 2012 [NDcPP] collaborative Protection Profile for Network Devices+ Errata 20180314, Version 2.0e, 14 March 2018 [800-56A] NIST Special Publication 800-56A, March 2007 [800-56B] NIST Special Publication 800-56B Recommendation for Pair-Wise, August 2009 [FIPS 140-2] FIPS PUB 140-2 Federal Information Processing Standards Publication [FIPS PUB 186-3] FIPS PUB 186-3 Federal Information Processing Standards Publication Digital Signature Standard (DSS) June, 2009 [800-90] NIST Special Publication 800-90A Recommendation for Random Number Generation Using Deterministic Random Bit Generators January 2012 [FIPS PUB 180-3] FIPS PUB 180-3 Federal Information Processing Standards Publication Secure Hash Standard (SHS) October 2008