Apple Inc. Apple OS X CoreCrypto Kernel Module, v6.0 FIPS 140-2 Non-Proprietary Security Policy Document Control Number FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 March, 2016 Prepared for: Apple Inc. 1 Infinite Loop Cupertino, CA 95014 www.apple.com Prepared by: atsec information security Corp. 9130 Jollyville Road, Suite 260 Austin, TX 78759 www.atsec.com ©2016 Apple Inc. This document may be reproduced and distributed only in its original entirety without revision Table of Contents 1 INTRODUCTION ............................................................................................................................................... 4 1.1 PURPOSE ............................................................................................................................................................ 4 1.2 DOCUMENT ORGANIZATION / COPYRIGHT ................................................................................................................. 4 1.3 EXTERNAL RESOURCES / REFERENCES ....................................................................................................................... 4 Additional References .............................................................................................................................. 4 1.3.1 1.4 ACRONYMS ......................................................................................................................................................... 5 2 CRYPTOGRAPHIC MODULE SPECIFICATION ...................................................................................................... 7 2.1 MODULE DESCRIPTION .......................................................................................................................................... 7 Module Validation Level .......................................................................................................................... 7 2.1.1 Module components ................................................................................................................................ 7 2.1.2 Tested Platforms ...................................................................................................................................... 8 2.1.3 2.2 MODES OF OPERATION .......................................................................................................................................... 8 2.3 CRYPTOGRAPHIC MODULE BOUNDARY ................................................................................................................... 13 2.4 MODULE USAGE CONSIDERATIONS ........................................................................................................................ 13 3 CRYPTOGRAPHIC MODULE PORTS AND INTERFACES .......................................................................................15 4 ROLES, SERVICES AND AUTHENTICATION ........................................................................................................16 4.1 ROLES .............................................................................................................................................................. 16 4.2 SERVICES .......................................................................................................................................................... 16 4.3 OPERATOR AUTHENTICATION ................................................................................................................................ 21 5 PHYSICAL SECURITY ........................................................................................................................................22 6 OPERATIONAL ENVIRONMENT........................................................................................................................23 6.1 APPLICABILITY.................................................................................................................................................... 23 6.2 POLICY ............................................................................................................................................................. 23 7 CRYPTOGRAPHIC KEY MANAGEMENT .............................................................................................................24 7.1 RANDOM NUMBER GENERATION........................................................................................................................... 24 7.2 KEY / CSP GENERATION ...................................................................................................................................... 24 7.3 KEY / CSP ESTABLISHMENT .................................................................................................................................. 24 7.4 KEY / CSP ENTRY AND OUTPUT ............................................................................................................................ 24 7.5 KEY / CSP STORAGE ........................................................................................................................................... 24 7.6 KEY / CSP ZEROIZATION ...................................................................................................................................... 25 8 ELECTROMAGNETIC INTERFERENCE/ELECTROMAGNETIC COMPATIBILITY (EMI/EMC) ....................................26 9 SELF-TESTS ......................................................................................................................................................27 9.1 POWER-UP TESTS .............................................................................................................................................. 27 Cryptographic Algorithm Tests .............................................................................................................. 27 9.1.1 Software / Firmware Integrity Tests ...................................................................................................... 27 9.1.2 Critical Function Tests ............................................................................................................................ 27 9.1.3 9.2 CONDITIONAL TESTS ........................................................................................................................................... 27 Continuous Random Number Generator Test ........................................................................................ 28 9.2.1 Pair-wise Consistency Test ..................................................................................................................... 28 9.2.2 SP 800-90A Assurance Tests .................................................................................................................. 28 9.2.3 Critical Function Test .............................................................................................................................. 28 9.2.4 10 DESIGN ASSURANCE ...................................................................................................................................29 10.1 CONFIGURATION MANAGEMENT ........................................................................................................................... 29 10.2 DELIVERY AND OPERATION ................................................................................................................................... 29 10.3 DEVELOPMENT .................................................................................................................................................. 29 10.4 GUIDANCE ........................................................................................................................................................ 29 10.4.1 Cryptographic Officer Guidance ............................................................................................................ 29 ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 2 of 30 User Guidance ....................................................................................................................................... 29 10.4.2 11 MITIGATION OF OTHER ATTACKS .................................................................................................................30 List of Tables Table 1: Module Validation Level ..................................................................................................7 Table 2: Tested Platforms .............................................................................................................8 Table 3: Approved Security Functions......................................................................................... 10 Table 4: Non-Approved Function ................................................................................................ 13 Table 5: Roles ............................................................................................................................ 16 Table 6: Approved and Allowed Services in Approved Mode ....................................................... 19 Table 6b: Non-Approved Services in Non-Approved Mode ......................................................... 21 Table 7: Cryptographic Algorithm Tests ....................................................................................... 27 List of Figures Figure 1: Logical Block Diagram ................................................................................................. 13 ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 3 of 30 1 Introduction 1.1 Purpose This document is a non-proprietary Security Policy for the Apple OS X CoreCrypto Kernel Module, v6.0. It describes the module and the FIPS 140-2 cryptographic services it provides. This document also defines the FIPS 140-2 security rules for operating the module. This document was prepared in fulfillment of the FIPS 140-2 requirements for cryptographic modules and is intended for security officers, developers, system administrators, and end-users. FIPS 140-2 details the requirements of the Governments of the U.S. and Canada for cryptographic modules, aimed at the objective of protecting sensitive but unclassified information. For more information on the FIPS 140-2 standard and validation program please refer to the NIST website at http://csrc.nist.gov/cryptval. Throughout the document “Apple OS X CoreCrypto Kernel Module, v6.0.”, “cryptographic module”, “CoreCrypto KEXT” or “the module” are used interchangeably to refer to the Apple OS X CoreCrypto Kernel Module, v6.0. Document Organization / Copyright 1.2 This non-proprietary Security Policy document may be reproduced and distributed only in its original entirety without any revision, ©2016 Apple Inc. 1.3 External Resources / References The Apple website (http://www.apple.com) contains information on the full line of products from Apple Inc. For a detailed overview of the operating system OS X and its security properties refer to [OS X] and [SEC]. For details on OS X releases with their corresponding validated modules and Crypto Officer Role Guides refer to the Apple Knowledge Base Article HT201159 - “Product security certifications, validations, and guidance for OS X” (https://support.apple.com/en- us/HT201159) The Cryptographic Module Validation Program website (http://csrc.nist.gov/groups/STM/cmvp/index.html) contains links to the FIPS 140-2 certificate and Apple, Inc. contact information. 1.3.1 Additional References FIPS 140-2 Federal Information Processing Standards Publication, “FIPS PUB 140-2 Security Requirements for Cryptographic Modules,” Issued May-25-2001, Effective 15-Nov- 2001, Location: http://csrc.nist.gov/groups/STM/cmvp/standards.html FIPS 180-4 Federal Information Processing Standards Publication 180-4, March 2012, Secure Hash Standard (SHS) FIPS 197 Federal Information Processing Standards Publication 197, November 26, 2001 Announcing the ADVANCED ENCRYPTION STANDARD (AES) RSA Laboratories, “PKCS#7 v1.5: Cryptographic Message Syntax Standard,” PKCS7 1993. Location: http://www.rsa.com/rsalabs/node.asp?id=2129 RSA Laboratories, “PKCS#3 v1.4: Diffie-Hellman Key Agreement Standard,” 1993. PKCS3 Location: http://www.rsa.com/rsalabs/node.asp?id=2126 ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 4 of 30 NIST, “Implementation Guidance for FIPS PUB 140-2 and the Cryptographic IG Module Validation Program,” January 11, 2016 Location: http://csrc.nist.gov/groups/STM/cmvp/standards.html OS X OS X Technical Overview Location: https://developer.apple.com/library/mac/#documentation/MacOSX/Conceptual/OSX_T echnology_Overview/About/About.html SEC Security Overview Location: https://developer.apple.com/library/mac/navigation/#section=Topics&topic=Security SP800-57P1 NIST Special Publication 800-57, “Recommendation for Key Management – Part 1: General (Revised),” March 2007 SP 800-90A NIST Special Publication 800-90A, “Recommendation for Random Number Generation Using Deterministic Random Bit Generators (Revised),” January 2012 UG User Guide Location: https://developer.apple.com/library/mac/navigation/ 1.4 Acronyms Acronyms found in this document are defined as follows: AES Advanced Encryption Standard BS Block Size CAVP Cryptographic Algorithm Validation Program CBC Cipher Block Chaining mode of operation CFB Cipher Feedback mode of operation CMVP Cryptographic Module Validation Program CSP Critical Security Parameter CTR Counter mode of operation DES Data Encryption Standard DH Diffie-Hellman DMA Direct Memory Access DRBG Deterministic Random Bit Generator DS Digest Size ECB Electronic Codebook mode of operation ECC Elliptic Curve Cryptography EC Diffie-Hellman Diffie-Hellman based on ECC ECDSA DSA based on ECC E/D Encrypt/Decrypt ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 5 of 30 EMC Electromagnetic Compatibility EMI Electromagnetic Interference FIPS Federal Information Processing Standard FIPS PUB FIPS Publication GCM Galois/Counter Mode HMAC Hash-Based Message Authentication Code HW Hardware IPCU iPhone Configuration Utility KAT Known Answer Test KEK Key Encryption Key KEXT Kernel extension KDF Key Derivation Function KO 1 Triple-DES Keying Option 1: All three keys are independent KPI Kernel Programming Interface KS Key Size (Length) MAC Message Authentication Code NIST National Institute of Standards and Technology OFB Output Feedback (mode of operation) OS Operating System PBKDF Password-based Key Derivation Function PWCT Pair Wise Consistency Test RNG Random Number Generator SHS Secure Hash Standard SW Software Triple-DES Triple Data Encryption Standard TLS Transport Layer Security ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 6 of 30 2 Cryptographic Module Specification 2.1 Module Description The Apple OS X CoreCrypto Kernel Module, v6.0 is a software cryptographic module running on a multi-chip standalone general-purpose computer. The cryptographic services provided by the module are:   Data encryption / decryption Random number generation   Generation of hash values Key derivation   Message authentication Key generation  Signature generation / verification 2.1.1 Module Validation Level The module is intended to meet requirements of FIPS 140-2 security level 1 overall. The following table shows the security level for each of the eleven requirement areas of the validation. FIPS 140-2 Security Requirement Area Security Level Cryptographic Module Specification 1 Cryptographic Module Ports and Interfaces 1 Roles, Services and Authentication 1 Finite State Model 1 Physical Security N/A Operational Environment 1 Cryptographic Key Management 1 EMI/EMC 1 Self-Tests 1 Design Assurance 1 Mitigation of Other Attacks 1 Table 1: Module Validation Level 2.1.2 Module components In the following sections the components of the Apple OS X CoreCrypto Kernel Module, v6.0 are listed in detail. There are no components excluded from the validation testing. 2.1.2.1 Software components CoreCrypto has a KPI layer that provides consistent interfaces to the supported algorithms. These implementations include proprietary optimizations of algorithms that are fitted into the CoreCrypto framework. The CoreCrypto KEXT is linked dynamically into the OS X kernel. 2.1.2.2 Hardware components There is hardware acceleration for AES-NI within the cryptographic module boundary. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 7 of 30 2.1.3 Tested Platforms The module has been tested on the following platforms with and without AES-NI: Manufacturer Model Operating System Apple Inc. Mac mini with i5 CPU OS X El Capitan v10.11 Apple Inc. iMac with i7 CPU OS X El Capitan v10.11 Apple Inc. MacPro with Xeon CPU OS X El Capitan v10.11 Apple Inc. MacBook with Core M OS X El Capitan v10.11 Table 2: Tested Platforms 2.2 Modes of operation The Apple OS X CoreCrypto Kernel Module, v6.0 has an Approved and Non-Approved Mode of operation. The Approved Mode of operation is configured in the system by default and cannot be changed. If the device starts up successfully then CoreCrypto KEXT has passed all self-tests and is operating in the Approved Mode. Any calls to the Non-Approved security functions listed in Table 4 will cause the module to assume the Non-Approved Mode of operation. The module transitions back into FIPS mode immediately when invoking one of the approved ciphers as all keys and Critical Security Parameters (CSP) handled by the module are ephemeral and there are no keys and CSPs shared between any functions. A re-invocation of the self-tests or integrity tests is not required. Even when using this FIPS 140-2 non-approved mode, the module configuration ensures that the self-tests are always performed during initialization time of the module. The module contains multiple implementations of the same cipher as listed below. If multiple implementations of the same cipher are present, the module automatically selects which cipher is used based on internal heuristics. This includes the hardware-assisted AES implementation (AES-NI). Approved security functions are listed in Table 3. Column four (“Val. No.”) of Table 3 lists the validation numbers obtained from NIST based on the successful CAVP testing of the cryptographic algorithm implementations on the platforms referenced in Table 2 Refer to http://csrc.nist.gov/groups/STM/cavp/index.html for the current standards, test requirements, and special abbreviations used in the following table. Approved Security Functions Cryptographic Algorithm Options Validation Function Number Random [SP 800-90] DRBG CTR_DRBG (AES non-optimized) 1055, 1056, 1057, 1058 Number Generic-software implementation Generation; Key Size: 128 bit key size Symmetric key CTR_DRBG (AES optimized- 1051, 1052, 1053, 1054 generation software implementation): Key Size: 128 bit key size CTR_DRBG (AES-NI hardware 1047, 1048, 1049, 1050 implementation): Key Size: 128 bit key size ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 8 of 30 Cryptographic Algorithm Options Validation Function Number Symmetric [FIPS 197] AES Generic-software implementation 3793, 3794, 3795, 3796 Encryption and SP 800-38 A (non-optimized based on Decryption LibTomCrypt): SP 800-38 D Key sizes: 128/192/256 bits SP 800-38 E Block chaining modes: ECB, SP 800-38 F CBC, CCM, KW, XTS Optimized-assembler 3789, 3790, 3791, 3792 implementation: Key sizes: 128/192/256 bits Block chaining modes: ECB, CBC, XTS, KW AES-NI hardware implementation 3782, 3786, 3787, 3788 with optimized software implementation of block chaining modes:: Block chaining modes: ECB, CBC, KW, XTS Key sizes: 128/192/256 bits AES-NI hardware implementation 3781, 3783, 3784, 3785 with optimized software implementation of block chaining modes: Block chaining modes: CBC, KW, XTS Key sizes: 128/192/256 bits [SP 800-67] Triple- 3 key Triple-DES (All keys 2102, 2103, 2104, 2105 DES independent) ANSIX9.52-1 998 Block chaining modes: TECB, TCBC FIPS 46-3 SP 800-38A Appendix E Digital Signature FIPS186-4 RSA SigVerPKCS1.5 (1024/2048/3072) 1949, 1950, 1951, 1952 and Asymmetric PKCS #1.5 Key Generation [FIPS 186-4] ECDSA PKG: curves P-256, P-384 816, 817, 818, 819 ANSI X9.62 PKV: curves P-256, P-384 SIG(gen): curves P-256, P-384 SIG(ver): curves P-256, P-384 Message Digest [FIPS 180-4] SHS Generic-software implementation 3148, 3149, 3150, 3151 (non-optimized): SHA-1, SHA-2 ( 224, 256, 384, 512) Optimized-software 3036, 3037, 3038, 3039 implementation using SSE: SHA-1, SHA-2 ( 224, 256) ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 9 of 30 Cryptographic Algorithm Options Validation Function Number Optimized-software 3024, 3025, 3026, 3027 implementation not using SSE: SHA-1, SHA-2 ( 224, 256) Optimized-software 3028, 3029, 3030, 3031 implementation using AVX1: SHA-256 Optimized-software 3032, 3033, 3034, 3035 implementation using AVX2: SHA-256 Keyed Hash [FIPS 198] HMAC Generic-software implementation 2475, 2476, 2477, 2478 (non-optimized): KSBS SHA-1, SHA-2 ( 224, 256, 384, 512) Key Size: at least 112 bits Optimized-software 2370, 2371, 2372, 2373 implementation using SSE: KSBS SHA-1, SHA-2( 224, 256) Key Size: at least 112 bits Optimized-software 2358, 2359, 2360, 2361 implementation not using SSE: KSBS SHA-1, SHA-2 ( 224, 256) Key Size: at least 112 bits Optimized-software 2362, 2363, 2364, 2365 implementation using AVX1: SHA-256 Optimized-software 2366, 2367, 2368, 2369 implementation using AVX2: SHA-256 PBKDF SP 800-132 Password based key derivation Vendor Affirmed using HMAC with SHA-1 or SHA- 2 as pseudorandom function Table 3: Approved Security Functions CAVEAT: The module generates cryptographic keys whose strengths are modified by available entropy – 160-bits. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 10 of 30 Non-Approved Security Functions: Cryptographic Usage / Description Caveat Function AES Optimized-assembler implementation Non-compliant using AVX: Encryption / Decryption Block Chaining Mode: GCM 64 bit word Optimized-assembler implementation Non-compliant using SSE3: Encryption / Decryption Block Chaining Mode: GCM, CTR 64 bit word DES Encryption and decryption: key size 56 Non-Approved bit; Used for NFS support in the raccoon IPSec cipher suite as a last resort when AES and Triple-DES ciphers are not supported by the remote end. Triple-DES Optimized-assembler implementation: Non-compliant Encryption / Decryption Block Chaining Mode: CTR Triple-DES Encryption and Decryption: Non-Approved One key and two key implementation ANSI X9.63 Hash Based KDF Non-Approved RFC6637 KDF KDF based on RFC 6637 Non-Approved SP800-108 KBKDF Non-compliant Modes: Counter, Feedback SP800-56C KDF Non-Approved MD2 Hashing Non-Approved Digest size 128 bit MD4 Hashing Non-Approved Digest size 128 bit MD5 Hashing Non-Approved Digest size 128 bit RIPEMD Hashing Non-Approved Digest size 128, 160, 256, 320 bits ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 11 of 30 Cryptographic Usage / Description Caveat Function Ed25519 Key Agreement Non-Approved Sig(gen) Sig(ver) ECDSA PKG: curves P-192, P-224, P-521 Non-compliant PKV: curves P-192, P-224, P-521 SIG(gen): curves P-192, P-224, P-521 SIG(ver): curves P-192, P-224, P-521 ECDSA key generation for compact point Non-Approved representation of points Integrated Encryption/Decryption Non-Approved Encryption Scheme on elliptic curves RSA PKCS#1 v1.5 Non-compliant FIPS186-2 SIG(ver) Key sizes (modulus): 1536 bits, 4096 bits Hash algorithms: SHA-1, SHA-224, SHA-256, SHA-384, SHA-512 RSA OAEP Encryption and Decryption Non-Approved, but allowed: RSA (key wrapping; key establishment methodology provides between 112 and 150 bits of encryption strength; non-compliant less than 112 bits of encryption strength) CAST5 Encryption and decryption: key sizes 40 Non-Approved to 128 bits in 8-bit increments Blowfish Encryption and decryption Non-Approved RC2 Encryption and decryption: key size 8 to Non-Approved 1024 bits RC4 Encryption and decryption: key size 8 to Non-Approved 1024 bits Hash_DRBG Hash_DRBG using SHA1 derived from Non-compliant the SP800-90A without derivation function, without prediction resistance resistance, without support for personalizati HMAC_DRBG HMAC based RNG derived from SP800- Non-compliant 90A without prediction resistance ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 12 of 30 Cryptographic Usage / Description Caveat Function AES-CMAC AES-128 MAC generation Non-compliant OMAC (One- MAC generation Non-Approved Key CBC MAC) Table 4: Non-Approved Function The encryption strengths included in Table 4 for the key establishment methods are determined in accordance with FIPS 140-2 Implementation Guidance [IG] section 7.5 and NIST Special Publication 800-57 (Part1) [SP800-57P1]. 2.3 Cryptographic Module Boundary The physical boundary of the module is the physical boundary of the OS X device that contains the module. Consequently, the embodiment of the module is a multi-chip standalone cryptographic module. The logical module boundary is depicted in the logical block diagram given in Figure 1. Figure 1: Logical Block Diagram 2.4 Module Usage Considerations A user of the module must consider the following requirements and restrictions when using the module:  AES-GCM is constructed in accordance with SP800-38D section 8.2.2. Users should consult SP 800-38D, especially section 8, for all of the details and requirements of using AES-GCM mode. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 13 of 30  When using AES, the caller must obtain a reference to the cipher implementation via the functions of ccaes_[cbc|ecb|...]_[encrypt|decrypt]_mode.  When using SHA, the caller must obtain a reference to the cipher implementation via the functions ccsha[1|224|256|384|512]_di.  In case the module’s power is lost and then restored, the key used for the AES GCM encryption/decryption shall be re-distributed ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 14 of 30 3 Cryptographic Module Ports and Interfaces The underlying logical interfaces of the module are the C language Kernel Programming Interfaces (KPIs). In detail these interfaces are the following:  Data input and data output are provided in the variables passed in the KPI and callable service invocations, generally through caller-supplied buffers. Hereafter, KPIs and callable services will be referred to as “KPI.”  Control inputs which control the mode of the module are provided through dedicated parameters, namely the kernel module plist whose information is supplied to the module by the kernel module loader.  Status output is provided in return codes and through messages. Documentation for each KPI lists possible return codes. A complete list of all return codes returned by the C language KPIs within the module is provided in the header files and the KPI documentation. Messages are documented also in the KPI documentation. The module is optimized for library use within the OS X kernel and does not contain any terminating assertions or exceptions. It is implemented as an OS X kernel extension. The dynamically loadable library is loaded into the OS X kernel and its cryptographic functions are made available to OS X Kernel services only. Any internal error detected by the module is reflected back to the caller with an appropriate return code. The calling OS X Kernel service must examine the return code and act accordingly. There are two notable exceptions: (i) ECDSA does not return a key if the pair-wise consistency test fails; (ii) the DRBG algorithm loops a few iterations internally if the continuous test fails, eventually recovering from the error or causing a shutdown if the problem persists. The function executing FIPS 140-2 module self-tests does not return an error code but causes the system to panic if any self-test fails – see Section 9. The module communicates error status synchronously through the use of documented return codes indicating the module’s status. It is the responsibility of the caller to handle exceptional conditions in a FIPS 140-2 appropriate manner. Caller-induced or internal errors do not reveal any sensitive material to callers. Cryptographic bypass capability is not supported by the module. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 15 of 30 4 Roles, Services and Authentication This section defines the roles, services and authentication mechanisms and methods with respect to the applicable FIPS 140-2 requirements. 4.1 Roles The module supports a single instance of the two authorized roles: the Crypto Officer and the User. No support is provided for multiple concurrent operators or a maintenance operator. Role General Responsibilities and Services (details see below) User Utilization of services of the module listed in sections 2.1 and 4.2 Crypto Officer (CO) Utilization of services of the module listed in sections 2.1 and 4.2. Table 5: Roles 4.2 Services The module provides services to authorized operators of either the User or Crypto Officer roles according to the applicable FIPS 140-2 security requirements. Table 6 contains the cryptographic functions employed by the module in the Approved Mode. For each available service it lists, the associated role, the Critical Security Parameters (CSPs) and cryptographic keys involved, and the type(s) of access to the CSPs and cryptographic keys. CSPs contain security-related information (secret and private cryptographic keys, for example) whose disclosure or modification can compromise the main security objective of the module, namely the protection of sensitive information. The access types are denoted as follows:  R: the item is read or referenced by the service  W: the item is written or updated by the service  Z: the persistent item is zeroized by the service Service Roles CSPs & crypto Access C keys Type U S O E R Triple-DES X X Secret key R Encryption Input: plaintext, IV, key Output: ciphertext Decryption Input: ciphertext, IV, key Output: plaintext ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 16 of 30 Service Roles CSPs & crypto Access C keys Type U S O E R AES X X Secret key R Encryption Input: plaintext, IV, key Output: ciphertext Decryption Input: ciphertext, IV, key Output: plaintext AES Key Wrapping X X secret key R Encryption Input: plaintext, key Output: ciphertext Decryption Input: ciphertext, key Output: plaintext Secure Hash Generation X X None N/A Input: message Output: message digest HMAC generation X X Secret HMAC R key Input: HMAC key, message Output: HMAC value of message RSA signature verification X X RSA key pair R Input: the module n, the public key e, W the SHA algorithm (SHA-1/SHA -224/SHA-256/SHA-384/SHA- 512), a message m, a signature for the message Output: pass if the signature is valid, fail if the signature is invalid ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 17 of 30 Service Roles CSPs & crypto Access C keys Type U S O E R ECDSA X X ECDSA key pair R W Signature generation Input: message m, q, a, b, XG, YG, n, the SHA algorithm (SHA -224/SHA-256/SHA-384/SHA- 512) sender’s private key d Output: signature of m as a pair of r and s Signature verification Input: received message m’, signature in form on r’ and s’ pair, q, a, b, XG, YG, n, sender’s public key Q, the SHA algorithm (SHA-1/SHA -224/SHA-256/SHA-384/SHA- 512) Output: pass if the signature is valid, fail if the signature is invalid Random number generation X X Entropy input R string, Nonce, V Input: Entropy Input, Nonce, W and K Personalization String Z Output: Returned Bits ECDSA (key pair generation) X X Asymmetric key R pair Input: q, FR, a, b, W domain_parameter_seed, G, n, h. Z Output: private key d, public key Q PBKDF Password-based key X X Secret key, R derivation password W Input: encrypted key and password Z Output: plaintext key or Input: plaintext key and password Output: encrypted data ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 18 of 30 Service Roles CSPs & crypto Access C keys Type U S O E R Release all resources of symmetric X X AES/Triple-DES Z crypto function context key Input: context Output: N/A Release all resources of hash context X X HMAC key Z Input: context Output: N/A Release all resources of asymmetric X X Asymmetric keys Z crypto function context (ECDSA) Input: context Output: N/A Reboot X X N/A N/A Self-test X X Software integrity R key Show Status X X None N/A Table 6: Approved and Allowed Services in Approved Mode Service Roles Access Type USER CO AES encryption and decryption X X R Modes: GCM, CTR, CBC Integrated Encryption Scheme on elliptic X X R curves encryption and decryption DES encryption and decryption X X R Triple-DES encryption and decryption X X R Mode: CTR Triple-DES encryption and decryption with X X R One-Key and Two-Key implementations ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 19 of 30 Service Roles Access Type USER CO CAST5 encryption and decryption X X R Blowfish encryption and decryption X X R RC4 encryption and decryption X X R RC2 encryption and decryption X X R MD2 Hash X X R W MD4 Hash X X R W MD5 Hash X X R W RIPEMD Hash X X R W RSA Key Wrapping with RSAES-OAEP X X R RSA PKCS1-v1_5 Signature Verification X X R Key sizes: 1536 bits, 4096 bits W ECDSA Key Pair Generation for compact X X R point representation of points W ECDSA X X R W PKG: curves P-192, P-224, P-521 PKV: curves P-192, P-224, P-521 SIG(gen): curves P-192,P-224, P-521 SIG(ver): curves P-192,P-224 P-521 Ed25519 Key agreement, Signature X X R Generation, Signature Verification W SP800-56C Key Derivation Function X X R W Hash based Key Derivation Function using X X R ANSI X9.63 W SP800-108 Key Derivation Function X X R Modes: Feedback, Counter W ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 20 of 30 Service Roles Access Type USER CO RFC6637 Key Derivation Function X X R W AES-CMAC MAC Generation X X R W OMAC MAC Generation X X R W HMAC_DRGB Random Number Generation X X R W Hash_DRBG Random Number Generation X X R W Table 6b: Non-Approved Services in Non-Approved Mode 4.3 Operator authentication Within the constraints of FIPS 140-2 level 1, the module does not implement an authentication mechanism for operator authentication. The assumption of a role is implicit in the action taken. The module relies upon the operating system for any operator authentication. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 21 of 30 5 Physical Security The Apple OS X CoreCrypto Kernel Module, v6.0 is intended to operate on a multi-chip standalone platform. The device is comprised of production grade components and a production grade enclosure. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 22 of 30 6 Operational Environment The following sections describe the operational environment of the Apple OS X CoreCrypto Kernel Module, v6.0. 6.1 Applicability The Apple OS X CoreCrypto Kernel Module, v6.0 operates in a modifiable operational environment per FIPS 140-2 level 1 specifications. The module is included in OS X El Capitan v10.11, a commercially available general-purpose operating system executing on the hardware specified in section 2.1.3 6.2 Policy The operating system is restricted to a single-user mode of operation of the module (single-user mode; concurrent operators are explicitly excluded). FIPS Self-Test functionality is invoked along with mandatory FIPS 140-2 tests when the module is loaded into memory by the operating system. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 23 of 30 7 Cryptographic Key Management The following section defines the key management features available through the Apple OS X CoreCrypto Kernel Module, v6.0. 7.1 Random Number Generation The module uses a FIPS 140-2 approved deterministic random bit generator (DRBG) based on a block cipher as specified in NIST SP 800-90A. It is a CTR_DRBG with derivation function and without prediction resistance. Seeding is obtained by read_random (a true random number generator). read_random obtains entropy from interrupts generated by the devices and sensors attached to the system and maintains an entropy pool. The TRNG feeds entropy from the pool into the DRBG on demand. The TRNG provides 160-bits of entropy. 7.2 Key / CSP Generation The following approved key generation methods are used by the module:  The Approved DRBG specified in section 7.1 is used to generate asymmetric key pairs for the ECDSA algorithm. The module does not output any information or intermediate results during the key generation process. The DRBG itself is single-threaded. The cryptographic strength of the 192 and 256 bit AES keys as well as the ECDSA keys for the curve P-384, as modified by the available entropy, is limited to 160-bits. 7.3 Key / CSP Establishment The module provides key establishment services in the Approved Mode through the AES key wrapping and PBKDFv2 algorithm. The RSA key wrapping is non-approved but allowed. The PBKDFv2 function is provided as a service and returns the key derived from the provided password to the caller. The caller shall observe all requirements and should consider all recommendations specified in SP800-132 with respect to the strength of the generated key, including the quality of the password, the quality of the salt as well as the number of iterations. The implementation of the PBKDFv2 function requires the user to provide this information. 7.4 Key / CSP Entry and Output All keys are entered from, or output to, the invoking kernel service running on the same device. All keys entered into the module are electronically entered in plain text form. Keys are output from the module in plain text form if required by the calling kernel service. The same holds for the CSPs. 7.5 Key / CSP Storage The Apple OS X CoreCrypto Kernel Module, v6.0 considers all keys in memory to be ephemeral. They are received for use or generated by the module only at the command of the calling kernel service. The same holds for CSPs. The module protects all keys, secret or private, and CSPs through the memory protection mechanisms provided by OS X, including the separation between the kernel and user-space. No process can read the memory of another process. No user-space application can read the kernel memory. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 24 of 30 7.6 Key / CSP Zeroization Keys and CSPs are zeroized when the appropriate context object is destroyed or when the system is powered down. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 25 of 30 8 Electromagnetic Interference/Electromagnetic Compatibility (EMI/EMC) The EMI/EMC properties of the CoreCrypto KEXT are not meaningful for the software library. The devices containing the software components of the module have their own overall EMI/EMC rating. The validation test environments have FCC, part 15, Class B rating. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 26 of 30 9 Self-Tests FIPS 140-2 requires that the module performs self-tests to ensure the integrity of the module and the correctness of the cryptographic functionality at start up. In addition, the DRBG requires continuous verification. The FIPS Self-Tests functionality runs all required module self-tests. This functionality is invoked by the OS X Kernel startup process upon device initialization. If the self- tests succeed, the CoreCrypto KEXT instance is maintained in the memory of the OS X Kernel on the device and made available to each calling kernel service without reloading. All self-tests performed by the module are listed and described in this section. 9.1 Power-Up Tests The following tests are performed each time the Apple OS X CoreCrypto Kernel Module, v6.0 starts and must be completed successfully for the module to operate in the FIPS approved mode. If any of the following tests fails the system shuts down automatically. To run the self-tests on demand, the user may reboot the system. 9.1.1 Cryptographic Algorithm Tests Algorithm Modes Test Triple-DES CBC KAT (Known Answer Test) Separate encryption / decryption operations are performed AES implementations selected by the ECB, CBC KAT module for the corresponding Separate encryption / decryption environment operations are performed AES-128, AES-192, AES-256 DRBG N/A KAT SHA implementations selected by the N/A KAT module for the corresponding environment SHA-1, SHA-224, SHA-256, SHA-384, SHA-512 HMAC-SHA-1, HMAC-SHA-224, N/A KAT HMAC-SHA-256, HMAC-SHA-384, HMAC-SHA-512 ECDSA SIG(ver), SIG(gen) KAT, pair-wise consistency test RSA SIG(ver) KAT Table 7: Cryptographic Algorithm Tests 9.1.2 Software / Firmware Integrity Tests A software integrity test is performed on the runtime image of the Apple OS X CoreCrypto Kernel Module, v6.0. The CoreCrypto’s HMAC-SHA-256 is used as an approved algorithm for the integrity test. If the test fails, then the system shuts down automatically. 9.1.3 Critical Function Tests No other critical function test is performed on power up. 9.2 Conditional Tests The following sections describe the conditional tests supported by the Apple OS X CoreCrypto Kernel Module, v6.0. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 27 of 30 9.2.1 Continuous Random Number Generator Test The Apple OS X CoreCrypto Kernel Module, v6.0 performs a continuous random number generator test, whenever CTR_DRBG is invoked. In addition, the seed source implemented in the operating system kernel also performs a continuous self-test. 9.2.2 Pair-wise Consistency Test The Apple OS X CoreCrypto Kernel Module, v6.0 generates asymmetric keys and performs all required pair-wise consistency tests (signature generation and verification) with the newly generated key pairs. 9.2.3 SP 800-90A Assurance Tests The Apple OS X CoreCrypto Kernel Module, v6.0 performs a subset of the assurance tests as specified in section 11 of SP 800-90A, in particular it complies with the mandatory documentation requirements and performs know-answer tests and prediction resistance. 9.2.4 Critical Function Test No other critical function test is performed conditionally. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 28 of 30 10 Design Assurance 10.1 Configuration Management Apple manages and records source code and associated documentation files by using the revision control system called “Git”. Apple module hardware data, which includes descriptions, parts data, part types, bills of materials, manufacturers, changes, history, and documentation are managed and recorded. Additionally, configuration management is provided for the module’s FIPS documentation. The following naming/numbering convention for documentation is applied. _____ Example: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.0 Document management utilities provide access control, versioning, and logging. Access to the Git repository (source tree) is granted or denied by the server administrator in accordance with company and team policy. 10.2 Delivery and Operation The CoreCrypto KEXT is built into OS X El Capitan v10.11. For additional assurance, it is digitally signed. The Approved Mode is configured by default and cannot be changed by a user. 10.3 Development The Apple crypto module (like any other Apple software) undergoes frequent builds utilizing a “train” philosophy. Source code is submitted to the Build and Integration group (B & I). B & I builds, integrates and does basic sanity checking on the operating systems and apps that they produce. Copies of older versions are archived offsite in underground granite vaults. 10.4 Guidance The following guidance items are to be used for assistance in maintaining the module’s validated status while in use. 10.4.1 Cryptographic Officer Guidance The Approved Mode of operation is configured in the system by default and cannot be changed. If the device starts up successfully then CoreCrypto KEXT has passed all self-tests and is operating in the Approved Mode. 10.4.2 User Guidance The Approved Mode of operation is configured in the system by default. If the device starts up successfully then CoreCrypto KEXT has passed all self-tests and is operating in the Approved Mode. Kernel programmers that use the module API shall not attempt to invoke any API call directly and only adhere to defined interfaces through the kernel framework. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 29 of 30 11 Mitigation of Other Attacks The module protects against the utilization of known Triple-DES weak keys. The following keys are not permitted: {0x01,0x01,0x01,0x01,0x01,0x01,0x01,0x01}, {0xFE,0xFE,0xFE,0xFE,0xFE,0xFE,0xFE,0xFE}, {0x1F,0x1F,0x1F,0x1F,0x0E,0x0E,0x0E,0x0E}, {0xE0,0xE0,0xE0,0xE0,0xF1,0xF1,0xF1,0xF1}, {0x01,0xFE,0x01,0xFE,0x01,0xFE,0x01,0xFE}, {0xFE,0x01,0xFE,0x01,0xFE,0x01,0xFE,0x01}, {0x1F,0xE0,0x1F,0xE0,0x0E,0xF1,0x0E,0xF1}, {0xE0,0x1F,0xE0,0x1F,0xF1,0x0E,0xF1,0x0E}, {0x01,0xE0,0x01,0xE0,0x01,0xF1,0x01,0xF1}, {0xE0,0x01,0xE0,0x01,0xF1,0x01,0xF1,0x01}, {0x1F,0xFE,0x1F,0xFE,0x0E,0xFE,0x0E,0xFE}, {0xFE,0x1F,0xFE,0x1F,0xFE,0x0E,0xFE,0x0E}, {0x01,0x1F,0x01,0x1F,0x01,0x0E,0x01,0x0E}, {0x1F,0x01,0x1F,0x01,0x0E,0x01,0x0E,0x01}, {0xE0,0xFE,0xE0,0xFE,0xF1,0xFE,0xF1,0xFE}, {0xFE,0xE0,0xFE,0xE0,0xFE,0xF1,0xFE,0xF1}. ©2016 Apple Inc. Last update: 2016-03-08 Document Id: FIPS_CORECRYPTO_OSX_KS_SECPOL_2.1 Page 30 of 30