Public Common Criteria Information Technology Security Evaluation Project Cayuse Security Target Lite of Samsung S3FV9QM/S3FV9QK 32-bit RISC Microcontroller for Smart Card with optional Secure RSA and ECC Library including specific IC Dedicated Software Version 3.0 28th September 2012 CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 2 of 71 REVISION HISTORY UPDATES: Version Date Modification 1.0 30th Nov. 2011 Creation 2.0 28th Sep. 2012 IC version is updated 3.0 28th Sep. 2012 IC version is updated CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 3 of 71 CONTENTS 1 ST INTRODUCTION ................................................................................................................................. 4 1.1 SECURITY TARGET AND TOE REFERENCE............................................................................................. 4 1.2 TOE OVERVIEW AND TOE DESCRIPTION .............................................................................................. 4 1.3 INTERFACES OF THE TOE................................................................................................................... 12 1.4 TOE INTENDED USAGE ...................................................................................................................... 13 2 CONFORMANCE CLAIMS..................................................................................................................... 14 2.1 CC CONFORMANCE CLAIM ................................................................................................................. 14 2.2 PP CLAIM .......................................................................................................................................... 14 2.3 PACKAGE CLAIM ................................................................................................................................ 14 2.4 CONFORMANCE CLAIM RATIONALE...................................................................................................... 14 3 SECURITY PROBLEM DEFINITION...................................................................................................... 16 3.1 DESCRIPTION OF ASSETS ................................................................................................................... 16 3.2 THREATS ........................................................................................................................................... 17 3.3 ORGANIZATIONAL SECURITY POLICIES ................................................................................................ 23 3.4 ASSUMPTIONS ................................................................................................................................... 24 4 SECURITY OBJECTIVES....................................................................................................................... 27 4.1 SECURITY OBJECTIVES FOR THE TOE................................................................................................. 27 4.2 SECURITY OBJECTIVES FOR THE SECURITY IC EMBEDDED SOFTWARE DEVELOPMENT ENVIRONMENT.... 31 4.3 SECURITY OBJECTIVES FOR THE OPERATIONAL ENVIRONMENT ............................................................ 32 4.4 SECURITY OBJECTIVES RATIONALE..................................................................................................... 33 5 EXTENDED COMPONENTS DEFINITION............................................................................................. 36 5.1 DEFINITION OF THE FAMILY FCS_RNG............................................................................................... 36 5.2 DEFINITION OF THE FAMILY FMT_LIM................................................................................................. 37 5.3 DEFINITION OF THE FAMILY FAU_SAS................................................................................................ 38 6 IT SECURITY REQUIREMENTS ............................................................................................................ 40 6.1 SECURITY FUNCTIONAL REQUIREMENTS FOR THE TOE........................................................................ 40 6.2 TOE ASSURANCE REQUIREMENTS...................................................................................................... 52 6.3 SECURITY REQUIREMENTS RATIONALE................................................................................................ 53 7 TOE SUMMARY SPECIFICATION......................................................................................................... 63 7.1 LIST OF SECURITY FUNCTIONAL REQUIREMENTS ................................................................................. 63 8 ANNEX .................................................................................................................................................... 68 8.1 GLOSSARY......................................................................................................................................... 68 8.2 ABBREVIATIONS ................................................................................................................................. 70 8.3 LITERATURE....................................................................................................................................... 71 CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 4 of 71 1 ST INTRODUCTION This introductory chapter contains the following sections: 1.1 Security Target and TOE Reference 1.2 TOE Overview and TOE Description 1.3 Interfaces of the TOE 1.4 TOE Intended Usage 1.1 Security Target and TOE Reference The Security Target Lite version is 3.0 and dated 28th September 2012 The Security Target Lite is based on [5] Eurosmart Security IC Platform Protection Profile, Version 1.0, June 2007, BSI-PP-0035. The Protection Profile and the Security Target are built on Common Criteria version 3.1.  Title: Security Target Lite of S3FV9QM/S3FV9QK 32-Bit RISC Microcontroller for Smart Cards  Target of Evaluation: S3FV9QM/S3FV9QK  Provided by: Samsung Electronics Co., Ltd.  Common Criteria version : [1] Common Criteria, Part 1: Common Criteria for Information Technology Security Evaluation, Part 1: Introduction and General Model, Version 3.1, Revision 3, July 2009, CCMB-2009-07-001 [2] Common Criteria, Part 2: Common Criteria for Information Technology Security Evaluation, Part 2: Security Functional Components, Version 3.1, Revision 3, July 2009, CCMB-2009-07-002 [3] Common Criteria, Part 3: Common Criteria for Information Technology Security Evaluation, Part 3: Security Assurance Components, Version 3.1, Revision 3, July 2009, CCMB-2009-07-003 [4] Common Methodology for Information Technology Security Evaluation, Evaluation Methodology, Version 3.1, Revision 3, July 2009, CCMB-2009-07-004 1.2 TOE Overview and TOE Description 1.2.1 Introduction The Target of Evaluation (TOE), the S3FV9QM/S3FV9QK microcontroller featuring the TORNADO-E cryptographic coprocessor, is a smartcard integrated circuit which is composed of a processing unit, security components, contact based I/O ports, hardware circuit for testing purpose during the manufacturing process and volatile and non-volatile memories (hardware). The TOE also includes any IC Designer/Manufacturer proprietary IC Dedicated Software as long as it physically exists in the smartcard integrated circuit after being delivered by the IC Manufacturer. Such software (also known as IC firmware) is used for testing purpose during the manufacturing process but also provides additional services to facilitate the usage of the hardware and/or to provide additional services, including optional RSA/ECC public key cryptographic library, an [6]AIS31 compliant random number generator. The RSA/ECC library further includes the functionality of hash computation. The use for keyed hash operations like HMAC or similar security critical operations involving keys and other secrets, is not subject of this TOE and requires specific security improvements and DPA analysis including the CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 5 of 71 operating system, which is not part of this TOE. However, this functionality is intended to be used for signature generation and verification only. All other software is called Smartcard Embedded Software and is not part of the TOE. Regarding the RSA and ECC library the user has the possibility to tailor this IC Dedicated Software part of the TOE during the manufacturing process by deselecting the RSA and ECC library. Hence the TOE can be delivered with or without the functionality of the RSA and ECC library what’s resulting in two TOE configurations. This is considered in this Security Target and corresponding notes (indicated by “optional”) are added where required. If the user decides not to use the RSA/ECC cryptographic library, the library is not delivered to the user and the accompanying “Additional Specific Security Functionality (O.Add-Functions)” Rivest- Shamir-Adleman (RSA) and Elliptic Curve Cryptography (ECC) is not provided by the TOE. Deselecting RSA and ECC library means excluding the code implementing functionality, which the user decided not to use. Excluding the code of the deselected functionality has no impact on any other security policy of the TOE, it is exactly equivalent to the situation where the user decides just not to use the functionalit 1.2.2 TOE Definition The S3FV9QM/S3FV9QK single-chip CMOS micro-controller is designed and packaged specifically for "Smart Card" applications. The SC300 CPU architecture of the S3FV9QM/S3FV9QK microcontroller follows the Harvard style, that is, it has separate program memory and data memory. Both instruction and data can be fetched simultaneously without causing a stall, using separate paths for memory access. The main security features of the S3FV9QM/S3FV9QK integrated circuit are:  Security sensors or detectors including High and Low Temperature detectors, High and Low Frequency detectors, High and Low Supply Voltage detectors, Supply Voltage Glitch detectors, and Light detector  Life Cycle detector  High Frequency Filter and Reset Noise Filter  Active Shields against physical intrusive attacks  Dedicated tamper-resistant design based on synthesizable glue logic and secure topology  Dedicated hardware mechanisms against side-channel attacks such as Internal Variable Clock, Random Current Generator, Random Waits Generator, RAM and FLASH encryption mechanisms  Secure DES and AES Symmetric Cryptography support  Secure TORNADO-E coprocessor for the support of RSA and ECC cryptographic operations  Hardware True Random Number Generators (DTRNG) that meet P2 class of BSI-AIS31 (German Metric).  The IC Dedicated Software includes: - A modular arithmetic library for the support of RSA and ECC (with SHA) cryptographic operations (optional) - A Hardware True Random Number Generator (DTRNG) for AIS31-compliant Random Number Generation - A DTRNG library build around Hardware DTRNG together with a DTRNG application note that meet the “standard” level of ANSSI requirements (French metric) as well as P2 class of BSI-AIS31 (German Metric). CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 6 of 71 The main hardware blocks of the S3FV9QM/S3FV9QK Integrated Circuit are described in Figure 1 below: Figure 1. S3FV9QM/S3FV9QK Block Diagram *Note that only the Triple DES algorithm belongs to the TOE, not the Single DES. The TOE consists of the following Hardware and Software: TOE Hardware  1280Kbytes(S3FV9QM), 1024Kbytes(S3FV9QK) FLASH/ 35K bytes RAM/ 5K bytes Crypto. RAM/ 32K User ROM/ 8K Test ROM /512 Bytes Flash special area  32-bit Central Processing Unit (CPU)  Internal Voltage Regulator (IVR)  Detectors & Security Logic  A True random number generator (DTRNG) CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 7 of 71  Memory Protection Unit (MPU)  Triple DES cryptographic coprocessor with 112 or 168 bits key size  AES cryptographic coprocessor with 128 bits, 192bits and 256bits key size  TORNADO-E supporting modular multiplications for the operand size up to 4128-bit and modular additions/subtractions for the operand size up to 544-bit  Hardware UART for contact I/O modes  SWP Interface  Address & data buses  Internal Clock  Timers  Power on Reset  PARITY/ CRC-32 calculators TOE Software The TOE software comprises the following components:  Test ROM code that is used for testing the chip during production  The TORNADO-E Secure RSA/ECC library v1.2 (optional) TORNADO-E is a hardware coprocessor for high speed modular multiplications, modular additions and modular subtractions. The TORNADO-E Secure RSA/ECC library v1.2 is a software library built on the TORNADO-E coprocessor that provides high level interface for RSA and ECC cryptographic algorithms. The RSA functions of the library included in the TOE are:  RSA_KeyGen_Secure (RSA public/private key pair generation)  TND_RSA_SigSTD_Secure (RSA signature generation with the standard method)  TND_RSA_SigCRT_Secure (RSA signature generation with the CRT method)  TND_RSA_Verify (RSA signature verification)  RSA_R2modM_precompute_sec (R^2 value precomputation for the standard RSA)  RSA_R2modPandQ_precompute_sec (R^2 value precomputation for the CRT RSA) The functions TND_RSA_SigSTD_Secure and TND_RSA_SigCRT_Secure implement some countermeasures against SPA, DPA and DFA attacks. The RSA_KeyGen_Secure function implements some countermeasures against SPA and DFA attacks. . Finally, the RSA_R2modM_precompute_sec and RSA_R2modPandQ_precompute_sec functions implement some countermeasures against the fault attack. The TORNADO-E Secure RSA/ECC library provides a set of functions to implement ECC cryptographic algorithms. In particular, it provides some functions to implement the ECDSA signing/verifying and the ECDH key exchange protocol. The library implements ECC for general curves over prime fields of size from 192-bit to 521-bit and the only certain curves are in the scope of this evaluation. The ECC functions of the library included in the TOE are:  ECDSA_keygen (Ephemeral or static key pair generation for ECDSA signing/verifying)  ECDSA_sign_digest (ECDSA signature generation for a message digest)  ECDSA_verify_digest (ECDSA signature verification for a message digest) CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 8 of 71  ECDH_generate (ECDH secret key derivation) The functions ECDSA_keygen, ECDSA_sign_digest and ECDH_generate implement some countermeasures against SPA, DPA and DFA for protecting the private key. The function ECDSA_verify_digest implements some countermeasures against DFA. The base point is assumed to be public. Note1) The RSA/ECC library supports any valid elliptic curves over prime fields of size from 192-bit to 521-bit. However, the standard curves listed below whose security has been proven are in the scope of this evaluation. 1) [NIST curves]: Curves P-192, P-224, P-256, P-384, P-521 2) [Brainpool curves]: brainpoolP192r1, brainpoolP192t1, brainpoolP224r1, brainpoolP224t1, brainpoolP256r1, brainpoolP256t1, brainpoolP320r1, brainpoolP320t1, brainpoolP384r1, brainpoolP384t1, brainpoolP512r1, brainpoolP512t1 3) [SEC-recommended curves]: secp192k1, secp192r1, secp224k1, secp224r1, secp256k1, secp256r1, secp384r1, secp521r1 The TORNADO-E Secure RSA/ECC library provides the functions for calculating hash (digest) values using the SHA1, SHA224, SHA256, SHA384 and SHA512 algorithms as specified in [FIPS PUB 180-3], but only those related to SHA224, SHA256, SHA384 and SHA512 listed below are within the scope of this evaluation:  SHA224_init, SHA224_update, SHA224_final  SHA256_init, SHA256_update, SHA256_final  SHA384_init, SHA384_update, SHA384_final  SHA512_init, SHA512_update, SHA512_final These functions are not security relevant functions, i.e. they must not be used to hash security values like keys etc. There are implemented no countermeasures against side channel attacks. The TOE provides the functionality of hash computation if and only if the optional TORNADO- E Secure RSA/ECC library is delivered. .  A True Random Number Generator (DTRNG) that fulfills the requirements of AIS 31, Class P2 as well as the “standard” level of ANSSI (French metric).  Secure Boot Loader can download the encrypted user code with TDES CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 9 of 71 The TOE configuration is summarized in table 1 below: Item Type Item Version Form of delivery Hardware S3FV9QM/S3FV9QK 32- Bit RISC Microcontroller for Smart Card 3 Wafer or Module Software Test ROM Code 1.0 - Included in S3FV9QM/S3FV9QK Test ROM - The Test ROM Code is not part of the TOE. Software Secure Boot loader code 2.1 Included in S3FV9QM/S3FV9QK in ROM Software (optional) Secure RSA/ ECC Library 1.1 Software Library. This library is delivered as object file and is optionally integrated into user NVM code. * Note: This RSA and ECC library includes RSA library and ECC library, but the ECC library is out of TOE for the version 1.1. 1.2 Software Library. This library is delivered as object file and is optionally integrated into user NVM code. * Note : This RSA and ECC library includes RSA library and ECC library, and both libraries are in certification scope for the version 1.2. Software DTRNG 2 Software Library. This library is delivered as object file and is optionally integrated into user NVM code. Document Tornado-E RSA/ECC Library API Manual 1.32 Softcopy Document HW DTRNG and DTRNG library application note 1.2 Softcopy Document Hardware User’s manual 1.03 Softcopy Document Security Application Note 1.0 Softcopy Document Chip Delivery Specification 0.1 Softcopy Document Boot Loader Specification 0.4 Softcopy Table 1. TOE Configuration Note: The TOE can be delivered without the RSA/ECC crypto library. In this case the TOE does not provide the Additional Specific Security Functionality Rivest-Shamir-Adleman Cryptography and Elliptic Curve Cryptography (ECC) and Secure Hash Algorithm (SHA). CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 10 of 71 1.2.3 TOE Features CPU  SC300 32-bit core Memory  32K-byte Program Memory (ROM)  8K Test ROM  1280Kbytes(S3FV9QM) and 1024Kbytes(S3FV9QK) Data/Program Memory (FLASH)  35K-byte Data Memory (RAM)  5K-byte Crypto Memory (Crypto RAM) FLASH Write Operations  Min. 500,000 write/erase cycles  Data retention for min. 25 years Triple DES  Built-in hardware Triple DES accelerator  Circuit for resistance against SPA and DPA attacks AES  Built-in hardware AES accelerator  Circuit for resistance against SPA and DPA attacks Abnormal Condition Detectors and Filters  Abnormal detectors and filters Interrupts  Nested Vector Interrupt Controller Serial I/O Interface  UART for handling serial I/O interface in accordance with the ISO 7816 communication protocols SWP Interface  Full-duplex communication Reset and Power Down Mode  Power-on reset and external reset  Stop mode Random Number Generator  A True random number generator (DTRNG) Memory Protection Unit  Memory protection unit (MPU) up to 4 GB CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 11 of 71 Memory Encryption and Bus Scrambling  Static bus scrambling  Logical-to-physical address scramble  Automatic RAM encryption  FLASH encryption with User-defined value Timers  Two 16-Bit Timers  A 20-bit Watchdog Timer Parity and CRC calculator  CRC-32 calculator  Parity calculator Clock Sources  External clock: 1 MHz–10 MHz  Internal clock: up to 24MHz Operating Voltage Range  1.62 V - 5.5 V Operating Temperature  - 25°C to 85°C Package  Wafer  8/6-pin COB 1.2.4 TOE Life cycle The complex development and manufacturing processes of a Composite Product can be separated into seven distinct phases. The phases 2 and 3 of the Composite Product life cycle cover the IC development and production: - IC Development (Phase 2): - IC design, - IC Dedicated Software development, - the IC Manufacturing (Phase 3): - integration and photomask fabrication, - IC production, - IC testing, - preparation and - Pre-personalisation if necessary The Composite Product life cycle phase 4 can be included in the evaluation of the IC as an option: - the IC Packaging (Phase 4): - Security IC packaging (and testing), - Pre-personalisation if necessary. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 12 of 71 In addition, three important stages have to be considered in the Composite Product life cycle: - Security IC Embedded Software Development (Phase 1), - the Composite Product finishing process, preparation and shipping to the personalisation line for the Composite Product (Composite Product Integration Phase 5), - the Composite Product personalisation and testing stage where the User Data is loaded into the Security IC's memory (Personalisation Phase 6), - the Composite Product usage by its issuers and consumers (Operational Usage Phase 7) which may include loading and other management of applications in the field. Device is in Test mode Device is in Normal mode Figure 1: Definition of “TOE Delivery” and responsible Parties The Security IC Embedded Software is developed outside the TOE development in Phase 1. The TOE is developed in Phase 2 and produced in Phase 3. Then the TOE is delivered in form of wafers. The TOE can also be delivered in form of packaged products. In this case, the development and production of the TOE not only pertain to Phase 2 and 3 but to Phase 4 in addition. 1.3 Interfaces of the TOE  The physical interface of the TOE with the external environment is the entire surface of the IC  The electrical interface of the TOE with the external environment is made of the chip’s pads including the Vdd, RESETB, XCLK, GND, IO1 and SWP interface  The data interface of the TOE is made of the Contact I/O pads and SWP pads.  The software interface of the TOE with the hardware consists of Special Function Registers (SFR) and CPU instructions. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 13 of 71  The TRNG interface of the TOE is defined by the DTRNG library interface.  The RSA interface of the TOE is defined by the RSA/ECC library interface (optional).  The interface to the ECC and SHA calculations is defined from the RSA/ECC library interface (optional) 1.4 TOE Intended Usage The TOE is dedicated to applications such as:  Banking and finance applications for credit or debit cards, electronic purse (stored value cards) and electronic commerce.  Network based transaction processing such a mobile phones (GSM SIM cards), pay TV (subscriber and pay-per-view cards), communication highways (Internet access and transaction processing).  Transport and ticketing applications (access control cards).  Governmental cards (ID cards, health cards, driving licenses).  Multimedia applications and Digital Right Management protection. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 14 of 71 2 CONFORMANCE CLAIMS This chapter 2 contains the following sections: 2.1 CC Conformance Claim 2.2 PP Claim 2.3 Package Claim 2.4 Conformance Claim Rationale 2.1 CC Conformance Claim This Security target claims to be conformant to the Common Criteria version 3.1. Furthermore it claims to be CC Part 2 extended and CC Part 3 conformant. The extended Security Functional Requirements are defined in chapter 5. This Security Target has been built with the Common Criteria for Information Technology Security Evaluation; Version 3.1 which comprises [1] Common Criteria, Part 1: Common Criteria for Information Technology Security Evaluation, Part 1: Introduction and General Model, Version 3.1, Revision 3, July 2009, CCMB-2009-07-001 [2] Common Criteria, Part 2: Common Criteria for Information Technology Security Evaluation, Part 2: Security Functional Components, Version 3.1, Revision 3, July 2009, CCMB-2009-07-002 [3] Common Criteria, Part 3: Common Criteria for Information Technology Security Evaluation, Part 3: Security Assurance Components, Version 3.1, Revision 3, July 2009, CCMB-2009-07-003 [4] Common Methodology for Information Technology Security Evaluation, Evaluation Methodology, Version 3.1, Revision 3, July 2009, CCMB-2009-07-004 has been taken into account. 2.2 PP Claim This Security Target is strict compliant to the Security IC Platform Protection Profile [5]. The Security IC Platform Protection Profile is registered and certified by the Bundesamt für Sicherheit in der Informationstechnik (BSI) under the reference BSI-PP-0035, Version 1.0, dated 15.06.2007. This ST does not claim conformance to any other PP. 2.3 Package Claim The assurance level for this Security Target is EAL5 augmented with AVA_VAN.5 and ALC_DVS.2. 2.4 Conformance Claim Rationale This security target claims strict conformance only to one PP, the Security IC Platform Protection Profile [5]. The Evaluation Assurance Level (EAL) of the PP [5] is EAL 4 augmented with the assurance components ALC_DVS.2 and AVA_VAN.5. The Assurance Requirements of the TOE obtain the Evaluation Assurance Level 5 augmented with the assurance components ALC_DVS.2 and AVA_VAN.5 for the TOE. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 15 of 71 The Target of Evaluation (TOE) is a complete solution implementing a security integrated circuit (security IC) as defined in the PP [5] section 1.3.1, so the TOE is consistent with the TOE type in the PP [5]. The security problem definition of this security target is consistent with the statement of the security problem definition in the PP [5], as the security target claimed strict conformance to the PP [5]. Additional threats, organisational security policies and assumptions are introduced in chapter 3 of this ST, a rationale is given in chapter 4.4. The security objectives of this security target are consistent with the statement of the security objectives in the PP [5], as the security target claimed strict conformance to the PP [5]. Additional security objectives are added in chapter 4.1 of this ST, a rationale is given in chapter 4.4. The security requirements of this security target are consistent with the statement of the security requirements in the PP [5], as the security target claimed strict conformance to the PP [5]. Additional security requirements are added in chapter 6.1 of this ST, a rationale is given in chapter 6.3. All assignments and selections of the security functional requirements are done in the PP [5] and in this security target section 6.1. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 16 of 71 3 SECURITY PROBLEM DEFINITION This chapter 3 contains the following sections: 3.1 Description of Assets 3.2 Threats 3.3 Organizational Security Policies 3.4 Assumptions 3.1 Description of Assets Assets regarding the Threats The assets (related to standard functionality) to be protected are  the User Data,  the Security IC Embedded Software,  the security services provided by the TOE for the Security IC Embedded Software. The user (consumer) of the TOE places value upon the assets related to high-level security concerns: SC1 integrity of User Data and of the Security IC Embedded Software (while being executed/processed and while being stored in the TOE’s memories), SC2 confidentiality of User Data and of the Security IC Embedded Software (while being processed and while being stored in the TOE’s memories) SC3 correct operation of the security services provided by the TOE for the Security IC Embedded Software. The Security IC may not distinguish between User Data which are public known or kept confidential. Therefore the security IC shall protect the confidentiality and integrity of the User Data, unless the Security IC Embedded Software chooses to disclose or modify it. In particular integrity of the Security IC Embedded Software means that it is correctly being executed which includes the correct operation of the TOE’s functionality. Though the Security IC Embedded Software (normally stored in the ROM) will in many cases not contain secret data or algorithms, it must be protected from being disclosed, since for instance knowledge of specific implementation details may assist an attacker. The Protection Profile requires the TOE to provide one security service: the generation of random numbers by means of an physical Random Number Generator. The Security Target may require additional security services. It is essential that the TOE ensures the correct operation of all security services provided by the TOE for the Security IC Embedded Software. According to the Protection Profile there is the following high-level security concern related to security service: SC4 deficiency of random numbers. To be able to protect these assets the TOE shall protect its security functionality. Therefore critical information about the TOE shall be protected. Critical information includes:  logical design data, physical design data, IC Dedicated Software, and configuration data, CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 17 of 71  Initialisation Data and Pre-personalisation Data, specific development aids, test and characterisation related data, material for software development support, and photomasks. Such information and the ability to perform manipulations assist in threatening the above assets. Note that there are many ways to manipulate or disclose the User Data: (i) An attacker may manipulate the Security IC Embedded Software or the TOE. (ii) An attacker may cause malfunctions of the TOE or abuse Test Features provided by the TOE. Such attacks usually require design information of the TOE to be obtained. They pertain to all information about (i) the circuitry of the IC (hardware including the physical memories), (ii) the IC Dedicated Software with the parts IC Dedicated Test Software (if any) and IC Dedicated Support Software (if any), and (iii) the configuration data for the security functionality. The knowledge of this information enables or supports attacks on the assets. Therefore the TOE Manufacturer must ensure that the development and production of the TOE is secure so that no information is unintentionally made available for the operational phase of the TOE. The TOE Manufacturer must apply protection to support the security of the TOE. This not only pertains to the TOE but also to all information and material exchanged with the developer of the Security IC Embedded Software. This covers the Security IC Embedded Software itself if provided by the developer of the Security IC Embedded Software or any authentication data required to enable the download of software. This includes the delivery (exchange) procedures for Phase 1 and the Phases after TOE Delivery as far as they can be controlled by the TOE Manufacturer. These aspects enforce the usage of the supporting documents and the refinements of SAR defined in the protection profile. The information and material produced and/or processed by the TOE Manufacturer in the TOE development and production environment (Phases 2 up to TOE Delivery) can be grouped as follows:  logical design data,  physical design data,  IC Dedicated Software, Security IC Embedded Software, Initialisation Data and Pre- personalisation Data,  specific development aids,  test and characterisation related data,  material for software development support, and  photomasks and products in any form as long as they are generated, stored, or processed by the TOE Manufacturer. 3.2 Threats The following explanations help to understand the focus of the threats and objectives defined below. For example, certain attacks are only one step towards a disclosure of assets, others may directly lead to a compromise of the application security.  Manipulation of data (which may comprise any data, including code, stored in or processed by the Security IC) means that an attacker is able to alter a meaningful block of data. This should be considered for the threats T.Malfunction, T.Phys-Manipulation and T.Abuse-Func.  Manipulation of the TOE means that an attacker is able to deliberately deactivate or otherwise change the behaviour of a specific function in a manner which enables exploitation. This should be considered for the threat T.Malfunction, T.Phys-Manipulation and T.Abuse-Func. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 18 of 71  Disclosure of data (which may comprise any data, including code, stored in or processed by the Security IC) means that an attacker is realistically1 able to determine a meaningful block of data. This should be considered for the threats T.Leak-Inherent, T.Phys-Probing, T.Leak-Forced and T.Abuse-Func. The cloning of the functional behaviour of the Security IC on its physical and command interface is the highest level security concern in the application context. The cloning of that functional behaviour requires to (i) develop a functional equivalent of the Security IC Embedded Software, (ii) disclose, interpret and employ the secret User Data stored in the TOE, and (iii) develop and build a functional equivalent of the Security IC using the input from the previous steps. The Security IC is a platform for the Security IC Embedded Software which ensures that especially the critical User Data are stored and processed in a secure way (refer to below). The Security IC Embedded Software must also ensure that critical User Data are treated as required in the application context. In addition, the personalisation process supported by the Security IC Embedded Software (and perhaps by the Security IC in addition) must be secure. This last step is beyond the scope of the Protection Profile. As a result the threat “cloning of the functional behaviour of the Security IC on its physical and command interface” is averted by the combination of measures which split into those being evaluated according to the Protection Profile (Security IC) and those being subject to the evaluation of the Security IC Embedded Software or Security IC and the corresponding personalisation process. Therefore, functional cloning is indirectly covered by the security concerns and threats described below. The high-level security concerns are refined below by defining threats as required by the Common Criteria (refer to Figure 3). Note that manipulation of the TOE is only a means to threaten User Data or the Security IC Embedded Software and is not a success for the attacker in itself. T.Malfunction T.Phys-Probing T.Leak-Forced T.Abuse-Func T.Phys-Manipulation T.Leak-Inherent Figure 3: Standard Threats The high-level security concern related to security service is refined below by defining threats as required by the Common Criteria (refer to Figure 4). 1 taking into account the assumed attack potential (and for instance the probability of errors) CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 19 of 71 T.RND T.Mem-Access Figure 4: Threats related to security service The Security IC Embedded Software must contribute to averting the threats: At least it must not undermine the security provided by the TOE. The above security concerns are derived from considering the end-usage phase (Phase 7) since  Phase 1 and the Phases from TOE Delivery up to the end of Phase 6 are covered by assumptions and  the development and production environment starting with Phase 2 up to TOE Delivery are covered by an organisational security policy. The TOE’s countermeasures are designed to avert the threats described below. Nevertheless, they may be effective in earlier phases (Phases 4 to 6). The TOE is exposed to different types of influences or interactions with its outer world. Some of them may result from using the TOE only but others may also indicate an attack. The different types of influences or interactions are visualised in Figure 5. Due to the intended usage of the TOE all interactions are considered as possible. Figure 5: Interactions between the TOE and its outer world CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 20 of 71 An interaction with the TOE can be done through the physical interfaces (Number 7 – 9 in Figure 5) which are realised using contacts interface. Influences or interactions with the TOE also occurs through the chip surface (Number 1 – 6 in Figure 5). In Number 1 and 6 galvanic contacts are used. In Number 2 and 5 the influence (arrow directed to the chip) or the measurement (arrow starts from the chip) does not require a contact. Number 3 and 4 refer to specific situations where the TOE and its functional behaviour is not only influenced but definite changes are made by applying mechanical, chemical and other methods (such as 1, 2). Many attacks require a prior inspection and some reverse-engineering (Number 3). This demonstrates the basic building blocks of attacks. A practical attack will use a combination of these elements. 3.2.1 Standard Threats The TOE shall avert the threat “Inherent Information Leakage (T.Leak-Inherent)” as specified below. T.Leak-Inherent Inherent Information Leakage An attacker may exploit information which is leaked from the TOE during usage of the Security IC in order to disclose confidential data as part of the assets. No direct contact with the Security IC internals is required here. Leakage may occur through emanations, variations in power consumption, I/O characteristics, clock frequency, or by changes in processing time requirements. One example is the Differential Power Analysis (DPA). This leakage may be interpreted as a covert channel transmission but is more closely related to measurement of operating parameters, which may be derived either from direct (contact) measurements (Numbers 6 and 7 in Figure 5) or measurement of emanations (Number 5 in Figure 5) and can then be related to the specific operation being performed. The TOE shall avert the threat “Physical Probing (T.Phys-Probing)” as specified below. T.Phys-Probing Physical Probing An attacker may perform physical probing of the TOE in order (i) to disclose User Data, (ii) to disclose/reconstruct the Security IC Embedded Software or (iii) to disclose other critical information about the operation of the TOE to enable attacks disclosing or manipulating the User Data or the Security IC Embedded Software. Physical probing requires direct interaction with the Security IC internals (Numbers 5 and 6 in Figure 5). Techniques commonly employed in IC failure analysis and IC reverse engineering efforts may be used. Before that hardware security mechanisms and layout characteristics need to be identified (Number 3 in Figure 5). Determination of software design including treatment of User Data may also be a pre-requisite. This pertains to “measurements” using galvanic contacts or any type of charge interaction whereas manipulations are considered under the threat “Physical Manipulation (T.Phys-Manipulation)”. The threats “Inherent Information Leakage (T.Leak-Inherent)” and “Forced Information Leakage (T.Leak-Forced)“ may use physical probing but require complex signal processing in addition. The TOE shall avert the threat “Malfunction due to Environmental Stress (T.Malfunction)” as specified below. T.Malfunction Malfunction due to Environmental Stress An attacker may cause a malfunction of TSF or of the Security IC Embedded Software by applying environmental stress in order to (i) modify security CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 21 of 71 services of the TOE or (ii) modify functions of the Security IC Embedded Software (iii) deactivate or affect security mechanisms of the TOE to enable attacks disclosing or manipulating the User Data or the Security IC Embedded Software. This may be achieved by operating the Security IC outside the normal operating conditions (Numbers 1, 2 and 9 in Figure 5). The modification of security services of the TOE may e.g. affect the quality of random numbers provided by the random number generator up to undetected deactivation when the random number generator does not produce random numbers and the Security IC Embedded Software gets constant values. In another case errors are introduced in executing the Security IC Embedded Software. To exploit this an attacker needs information about the functional operation, e.g. to introduce a temporary failure within a register used by the Security IC Embedded Software with light or a power glitch. The TOE shall avert the threat “Physical Manipulation (T.Phys-Manipulation)” as specified below. T.Phys-Manipulation Physical Manipulation An attacker may physically modify the Security IC in order to (i) modify User Data, (ii) modify the Security IC Embedded Software, (iii) modify or deactivate security services of the TOE, or (iv) modify security mechanisms of the TOE to enable attacks disclosing or manipulating the User Data or the Security IC Embedded Software. The modification may be achieved through techniques commonly employed in IC failure analysis (Numbers 1, 2 and 4 in Figure 5) and IC reverse engineering efforts (Number 3 in Figure 5). The modification may result in the deactivation of a security feature. Before that hardware security mechanisms and layout characteristics need to be identified. Determination of software design including treatment of User Data may also be a pre-requisite. Changes of circuitry or data can be permanent or temporary. In contrast to malfunctions (refer to T.Malfunction) the attacker requires to gather significant knowledge about the TOE’s internal construction here (Number 3 in Figure 5). The TOE shall avert the threat “Forced Information Leakage (T.Leak-Forced)“ as specified below: T.Leak-Forced Forced Information Leakage An attacker may exploit information which is leaked from the TOE during usage of the Security IC in order to disclose confidential data as part of the assets even if the information leakage is not inherent but caused by the attacker. This threat pertains to attacks where methods described in “Malfunction due to Environmental Stress” (refer to T.Malfunction) and/or “Physical Manipulation” (refer to T.Phys-Manipulation) are used to cause leakage from signals (Numbers 5, 6, 7 and 8 in Figure 5) which normally do not contain significant information about secrets. The TOE shall avert the threat “Abuse of Functionality (T.Abuse-Func)” as specified below. T.Abuse-Func Abuse of Functionality An attacker may use functions of the TOE which may not be used after TOE Delivery in order to (i) disclose or manipulate User Data, (ii) manipulate (explore, bypass, deactivate or change) security services of the TOE or (iii) manipulate (explore, bypass, deactivate or change) functions of the Security CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 22 of 71 IC Embedded Software or (iv) enable an attack disclosing or manipulating the User Data or the Security IC Embedded Software. 3.2.2 Threats related to security services The TOE shall avert the threat “Deficiency of Random Numbers (T.RND)” as specified below. T.RND Deficiency of Random Numbers An attacker may predict or obtain information about random numbers generated by the TOE for instance because of a lack of entropy of the random numbers provided. An attacker may gather information about the produced random numbers which might be a problem because they may be used for instance to generate cryptographic keys. Here the attacker is expected to take advantage of statistical properties of the random numbers generated by the TOE without specific knowledge about the TOE’s generator. Malfunctions or premature ageing are also considered which may assist in getting information about random numbers. 3.2.3 Threats related to additional TOE Specific Functionality The TOE shall avert the additional threat “Memory Access Violation (T.Mem-Access)” as specified below. T.Mem-Access Memory Access Violation Parts of the IC Smartcard Embedded Software may cause security violations by accidentally or deliberately accessing restricted data (which may include code). Any restrictions are defined by the security policy of the specific application context and must be implemented by the Smartcard IC Embedded Software. Clarification: This threat does not address the proper definition and management of the security rules implemented by the Security IC Embedded Software, this being software design and correctness issue. This threat addresses the reliability of the abstract machine targeted by the software implementation. To avert the threat, the set of access rules provided by this TOE should be undefeated if operated according to the provided guidance. The threat is not realized if the Security IC Embedded Software is designed or implemented to grant access to restricted information. It is realized if an implemented access denial is granted under unexpected conditions or if the execution machinery does not effectively control a controlled access. Here the attacker is expected to (i) take advantage of flaws in the design and/or the implementation of the TOE memory access rules (refer to T.Abuse-Func but for functions available after TOE delivery), (ii)introduce flaws by forcing operational conditions (refer to T.Malfunction) and/or by physical manipulation (refer to T.Phys-Manipulation). This attacker is expected to have a high level potential of attack. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 23 of 71 3.3 Organizational Security Policies The following Figure 6 shows the policies applied in this Security Target. P.Process-TOE P.Add-Functions Figure 6: Policies The IC Developer / Manufacturer must apply the policy “Protection during TOE Development and Production (P.Process-TOE)” as specified below. P.Process-TOE Protection during TOE Development and Production An accurate identification must be established for the TOE. This requires that each instantiation of the TOE carries this unique identification. The accurate identification is introduced at the end of the production test in phase 3. Therefore the production environment must support this unique identification. The information and material produced and/or processed by the TOE Manufacturer in the TOE development and production environment (Phases 2 up to TOE Delivery) can be grouped as follows:  logical design data,  physical design data,  IC Dedicated Software, Security IC Embedded Software, Initialisation Data and Pre- personalisation Data,  specific development aids,  test and characterisation related data,  material for software development support, and  photomasks and products in any form as long as they are generated, stored, or processed by the TOE Manufacturer. The TOE provides specific security functionality which can be used by the Smartcard Embedded Software. In the following specific security functionality is listed which is not derived from threats identified for the TOE’s environment because it can only be decided in the context of the smartcard application, against which threats the Smartcard Embedded Software will use the specific security functionality. The IC Developer / Manufacturer must apply the policy “Additional Specific Security Functionality (P.Add-Functions)” as specified below. P.Add-Functions Additional Specific Security Functionality The TOE shall provide the following specific security functionality to the Smartcard Embedded Software:  Triple Data Encryption Standard (3DES)  Advanced Encryption Standard (AES) CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 24 of 71  Rivest-Shamir-Adleman (RSA) public key asymmetric cryptography (optional)  Elliptic Curve Cryptography (ECC) and Secure Hash Algorithm (SHA) (optional) Note: The TOE can be delivered without the RSA/ECC crypto library. In this case the TOE does not provide the Additional Specific Security Functionality Rivest- Shamir-Adleman Cryptography and Elliptic Curve Cryptography (ECC) and Secure Hash Algorithm (SHA). 3.4 Assumptions The following Figure 6 shows the assumptions applied in this Security Target. Figure 7: Assumptions The intended usage of the TOE is twofold, depending on the Life Cycle Phase: (i) The Security IC Embedded Software developer uses it as a platform for the Security IC software being developed. The Composite Product Manufacturer (and the consumer) uses it as a part of the Security IC. The Composite Product is used in a terminal which supplies the Security IC (with power and clock) and (at least) mediates the communication with the Security IC Embedded Software. Before being delivered to the consumer the TOE is packaged. Many attacks require the TOE to be removed from the carrier. Though this extra step adds difficulties for the attacker no specific assumptions are made here regarding the package. Appropriate “Protection during Packaging, Finishing and Personalisation (A.Process-Sec-IC)” must be ensured after TOE Delivery up to the end of Phase 6, as well as during the delivery to Phase 7 as specified below. A.Process-Sec-IC Protection during Packaging, Finishing and Personalisation It is assumed that security procedures are used after delivery of the TOE by the TOE Manufacturer up to delivery to the consumer to maintain confidentiality and integrity of the TOE and of its manufacturing and test data (to prevent any possible copy, modification, retention, theft or unauthorised use). This means that the Phases after TOE Delivery are assumed to be protected appropriately. A.Process-Sec-IC A.Plat-Appl A.Key-Function A.Resp-Appl CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 25 of 71 The information and material produced and/or processed by the Security IC Embedded Software Developer in Phase 1 and by the Composite Product Manufacturer can be grouped as follows:  the Security IC Embedded Software including specifications, implementation and related documentation,  pre-personalisation and personalisation data including specifications of formats and memory areas, test related data,  the User Data and related documentation, and  material for software development support as long as they are not under the control of the TOE Manufacturer. Details must be defined in the Protection Profile or Security Target for the evaluation of the Security IC Embedded Software and/or Security IC. The developer of the Security IC Embedded Software must ensure the appropriate “Usage of Hardware Platform (A.Plat-Appl)” while developing this software in Phase 1 as specified below. A.Plat-Appl Usage of Hardware Platform The Security IC Embedded Software is designed so that the requirements from the following documents are met: (i) TOE guidance documents (refer to the Common Criteria assurance class AGD) such as the hardware data sheet, and the hardware application notes, and (ii) findings of the TOE evaluation reports relevant for the Security IC Embedded Software as documented in the certification report. Note that particular requirements for the Security IC Embedded Software are often not clear before considering a specific attack scenario during vulnerability analysis of the Security IC (AVA_VAN). A summary of such results is provided in the document "ETR for composite evaluation" (ETR-COMP). This document can be provided for the evaluation of the composite product. The ETR-COMP may also include guidance for additional tests being required for the combination of hardware and software. The TOE evaluation must be completed before evaluation of the Security IC Embedded Software can be completed. The TOE evaluation can be conducted before and independent from the evaluation of the Security IC Embedded Software. The developer of the Security IC Embedded Software must ensure the appropriate “Treatment of User Data (A.Resp-Appl)” while developing this software in Phase 1 as specified below. A.Resp-Appl Treatment of User Data All User Data are owned by Security IC Embedded Software. Therefore, it must be assumed that security relevant User Data (especially cryptographic keys) are treated by the Security IC Embedded Software as defined for its specific application context. The application context specifies how the User Data shall be handled and protected. The evaluation of the Security IC according to this Security Target is conducted on generalized application context. The concrete requirements for the Security IC Embedded Software shall be defined in the Protection Profile respective Security Target for the Security IC Embedded Software. The Security IC can not prevent any compromise or modification of User Data by malicious Security IC Embedded Software. The assumption A.Resp-Appl ensures that the Security IC Embedded Software follows the security rules of the application context. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 26 of 71 The developer of the Smartcard Embedded Software must ensure the appropriate “Usage of Key-dependent Functions (A.Key-Function)” while developing this software in Phase 1 as specified below. A.Key-Function Usage of Key-dependent Functions Key-dependent functions (if any) shall be implemented in the Smartcard Embedded Software in a way that they are not susceptible to leakage attacks (as described under T.Leak-Inherent and T.Leak-Forced). Note that here the routines which may compromise keys when being e xecuted are part of the Smartcard Embedded Software. In contrast to this the threats T.Leak-Inherent and T.Leak-Forced address (i) the cryptographic routines which are part of the TOE and (ii) the processing of User Data including cryptographic keys. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 27 of 71 4 SECURITY OBJECTIVES This chapter Security Objectives contains the following sections: 4.1 Security Objectives for the TOE 4.2 Security Objectives for the IC Embedded Software development Environment 4.3 Security Objectives for the operational Environment 4.4 Security Objectives Rationale 4.1 Security Objectives for the TOE According to the Protection Profile[BSI-PP-0035] there are the following standard high-level security goals: SG1 maintain the integrity of User Data and of the Security IC Embedded Software (when being executed/processed and when being stored in the TOE’s memories) as well as SG2 maintain the confidentiality of User Data and of the Security IC Embedded Software (when being processed and when being stored in the TOE’s memories). The Security IC may not distinguish between User Data which are public known or kept confidential. Therefore the security IC shall protect the confidentiality and integrity of the User Data, unless the Security IC Embedded Software chooses to disclose or modify it. In particular integrity of the Security IC Embedded Software means that it is correctly being executed which includes the correct operation of the TOE’s functionality. Though the Security IC Embedded Software (normally stored in the ROM) will in many cases not contain secret data or algorithms, it must be protected from being disclosed, since for instance knowledge of specific implementation details may assist an attacker. SG3 maintain the correct operation of the security services provided by the TOE for the Security IC Embedded Software. SG4 provide random numbers. These standard high-level security goals are refined below by defining security objectives as required by the Common Criteria (refer to Figure 8). Note that the integrity of the TOE is a mean to reach these objectives. Figure 8: Standard Security Objectives O.Phys-Manipulation O.Malfunction O.Phys-Probing O.Leak-Inherent O.Abuse-Func O.Leak-Forced O.Identification CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 28 of 71 Figure 9: Security Objectives related to Specific Functionality Standard Security Objectives The TOE shall provide “Protection against Inherent Information Leakage (O.Leak-Inherent)” as specified below. O.Leak-Inherent Protection against Inherent Information Leakage The TOE must provide protection against disclosure of confidential data (User Data or TSF data) stored and/or processed in the Smartcard IC  by measurement and analysis of the shape and amplitude of signals (for example on the power, clock, or I/O lines) and  by measurement and analysis of the time between events found by measuring signals (for instance on the power, clock, or I/O lines). This objective pertains to measurements with subsequent complex signal processing whereas O.Phys-Probing is about direct measurements on elements on the chip surface. Details correspond to an analysis of attack scenarios which is not given here. The TOE shall provide “Protection against Physical Probing (O.Phys-Probing)” as specified below. O.Phys-Probing Protection against Physical Probing The TOE must provide protection against disclosure of User Data, against the disclosure/reconstruction of the Smartcard Embedded Software or against the disclosure of other critical operational information. This includes protection against  measuring through galvanic contacts which is direct physical probing on the chips surface except on pads being bonded (using standard tools for measuring voltage and current) or  measuring not using galvanic contacts but other types of physical interaction between charges (using tools used in solid-state physics research and IC failure analysis) with a prior  reverse-engineering to understand the design and its properties and functions. The TOE must be designed and fabricated so that it requires a high combination of complex equipment, knowledge, skill, and time to be able to derive detailed design information or other information which could be used to compromise security through such a physical attack. O.RNG CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 29 of 71 The TOE shall provide “Protection against Malfunctions (O.Malfunction)” as specified below. O.Malfunction Protection against Malfunctions The TOE must ensure its correct operation. The TOE must prevent its operation outside the normal operating conditions where reliability and secure operation has not been proven or tested. This is to prevent errors. The environmental conditions may include voltage, clock frequency, temperature, or external energy fields. Remark: A malfunction of the TOE may also be caused using a direct interaction with elements on the chip surface. This is considered as being a manipulation (refer to the objective O.Phys-Manipulation) provided that detailed knowledge about the TOE´s internal construction is required and the attack is performed in a controlled manner. The TOE shall provide “Protection against Physical Manipulation (O.Phys-Manipulation)” as specified below. O.Phys-Manipulation Protection against Physical Manipulation The TOE must provide protection against manipulation of the TOE (including its software and TSF data), the Smartcard Embedded Software and the User Data. This includes protection against  reverse-engineering (understanding the design and its properties and functions),  manipulation of the hardware and any data, as well as  controlled manipulation of memory contents (User Data). The TOE must be designed and fabricated so that it requires a high combination of complex equipment, knowledge, skill, and time to be able to derive detailed design information or other information which could be used to compromise security through such a physical attack. The TOE shall provide “Protection against Forced Information Leakage (O.Leak-Forced)“ as specified below: O.Leak-Forced Protection against Forced Information Leakage The Security IC must be protected against disclosure of confidential data processed in the Security IC (using methods as described under O.Leak- Inherent) even if the information leakage is not inherent but caused by the attacker  by forcing a malfunction (refer to “Protection against Malfunction due to Environmental Stress (O.Malfunction)” and/or  by a physical manipulation (refer to “Protection againstPhysical Manipulation (O.Phys-Manipulation)”. If this is not the case, signals which normally do not contain significant information about secrets could become an information channel for a leakage attack. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 30 of 71 The TOE shall provide “Protection against Abuse of Functionality (O.Abuse-Func)” as specified below. O.Abuse-Func Protection against Abuse of Functionality The TOE must prevent that functions of the TOE which may not be used after TOE Delivery can be abused in order (i) to disclose critical User Data, (ii) to manipulate critical User Data of the Smartcard Embedded Software, (iii) to manipulate Soft-coded Smartcard Embedded Software or (iv) bypass, deactivate, change or explore security features or functions of the TOE. Details depend, for instance, on the capabilities of the Test Features provided by the IC Dedicated Test Software which are not specified here. The TOE shall provide “TOE Identification (O.Identification)“ as specified below: O.Identification TOE Identification The TOE must provide means to store Initialisation Data and Pre- personalisation Data in its non-volatile memory. The Initialisation Data (or parts of them) are used for TOE identification. Security Objectives related to Specific Functionality (referring to SC4) The TOE shall provide “Random Numbers (O.RND)” as specified below. O.RND Random Numbers The TOE will ensure the cryptographic quality of random number generation. For instance random numbers shall not be predictable and shall have sufficient entropy. The TOE will ensure that no information about the produced random numbers is available to an attacker since they might be used for instance to generate cryptographic keys. Security Objectives for Added Function The TOE shall provide “Additional Specific Security Functionality (O.Add-Functions)” as specified below. O.Add-Functions Additional Specific Security Functionality The TOE must provide the following specific security functionality to the Smartcard Embedded Software:  Triple Data Encryption Standard (3DES)  Advanced Encryption Standard (AES)  Rivest-Shamir-Adleman (RSA) public key asymmetric cryptography (optional)  Elliptic Curve Cryptography (ECC) and Secure Hash Algorithm (SHA).(optional) Note: The TOE can be delivered without the RSA/ECC crypto library. In this case the TOE does not provide the Additional Specific Security Functionality Rivest- Shamir-Adleman Cryptography and Elliptic Curve Cryptography (ECC) and Secure Hash Algorithm (SHA). CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 31 of 71 The TOE shall provide “Area based Memory Access Control (O.Mem-Access)” as specified below. O.Mem-Access Area based Memory Access Control The TOE must provide the Smartcard Embedded Software with the capability to define restricted access memory areas. The TOE must then enforce the partitioning of such memory areas so that access of software to memory areas is controlled as required, for example, in a multi-application environment. 4.2 Security Objectives for the Security IC Embedded Software Development Environment The development of the Security IC Embedded Software is outside the development and manufacturing of the TOE. The Security IC Embedded Software defines the operational use of the TOE. This section describes the security objectives for the operational environment enforced by the Security IC Embedded software. Phase 1 The Security IC Embedded Software shall provide “Usage of Hardware Platform (OE.Plat- Appl)” as specified below. OE.Plat-Appl Usage of Hardware Platform To ensure that the TOE is used in a secure manner the Security IC Embedded Software shall be designed so that the requirements from the following documents are met: (i) hardware data sheet for the TOE, (ii) data sheet of the IC Dedicated Software of the TOE, (iii) TOE application notes, other guidance documents, and (iv) findings of the TOE evaluation reports relevant for the Security IC Embedded Software as referenced in the certification report. The Security IC Embedded Software shall provide “Treatment of User Data (OE.Resp-Appl)” as specified below. OE.Resp-Appl Treatment of User Data Security relevant User Data (especially cryptographic keys) are treated by the Smartcard Embedded Software as required by the security needs of the specific application context. For example the Smartcard Embedded Software will not disclose security relevant user data to unauthorised users or processes when communicating with a terminal. 4.2.1 Clarification of “Usage of Hardware Platform (OE.Plat-Appl)” Regarding the cryptographic services this objective of the environment has to be clarified. The TOE supports cipher schemes as additional specific security functionality. If required the Smartcard Embedded Software shall use these cryptographic services of the TOE and their interface as specified. When key-dependent functions implemented in the Smartcard Embedded Software are just being executed, the Smartcard Embedded Software must provide protection CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 32 of 71 against disclosure of confidential data (User Data) stored and/or processed in the TOE by using the methods described under “Inherent Information Leakage (T.Leak-Inherent)” and “Forced Information Leakage (T.Leak-Forced)“. Regarding the area based access control this objective of the environment has to be clarified. For the separation of different applications the Smartcard Embedded Software (Operating System) may implement a memory management scheme based upon security mechanisms of the TOE. For the separation of different applications the Smartcard Embedded Software may implement a memory management scheme based upon security mechanisms of the TOE as required by the security policy defined for the specific application context. 4.2.2 Clarification of “Treatment of User Data (OE.Resp-Appl)” Regarding the cryptographic services this objective of the environment has to be clarified. By definition cipher or plain text data and cryptographic keys are User Data. The Smartcard Embedded Software shall treat these data appropriately, use only proper secret keys (chosen from a large key space) as input for the cryptographic function of the TOE and use keys and functions appropriately in order to ensure the strength of cryptographic operation. This means that keys are treated as confidential as soon as they are generated. The keys must be unique with a very high probability, as well as cryptographically strong. For example, it must be ensured that it is beyond practicality to derive the private key from a public key if asymmetric algorithms are used. If keys are imported into the TOE and/or derived from other keys, quality and confidentiality must be maintained. This implies that appropriate key management has to be realised in the environment. Regarding the area based access control this objective of the environment has to be clarified. The treatment of User Data is also required when a multi-application operating system is implemented as part of the Smartcard Embedded Software on the TOE. In this case the multi- application operating system should not disclose security relevant user data of one application to another application when it is processed or stored on the TOE. The treatment of User Data is still required when a multi-application operating system is implemented as part of the Smartcard Embedded Software on the TOE. In this case the multi- application operating system should not disclose security relevant user data of one application to another application when it is processed or stored on the TOE. 4.3 Security Objectives for the Operational Environment TOE Delivery up to the End of Phase 6 Appropriate “Protection during Packaging, Finishing and Personalisation (OE.Process-Sec-IC)” must be ensured after TOE Delivery up to the end of Phases 6, as well as during the delivery to Phase 7 as specified below. OE.Process-Sec-IC Protection during composite product manufacturing Security procedures shall be used after TOE Delivery up to delivery to the "consumer" to maintain confidentiality and integrity of the TOE and of its manufacturing and test data (to prevent any possible copy, modification, retention, theft or unauthorised use). This means that Phases after TOE Delivery up to the end of Phase 6 must be protected appropriately. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 33 of 71 4.3.1 Clarification of “Protection during Composite Product Manufacturing (OE.Process- Sec-IC)” The protection during packaging, finishing and personalization includes also the personalization process and the personalization data during Phase 4, Phase 5 and Phase 6. Since OE.Process-Sec-IC requires the Composite Product Manufacturer to implement those measures assumed in A.Process-Sec-IC, the assumption is covered by this objective. 4.4 Security Objectives Rationale Table 3 below gives an overview, how the assumptions, threats, and organisational security policies are addressed by the objectives. The text following after the table justifies this in detail. Assumption, Threat or Organisational Security Policy Security Objective Notes A.Plat-Appl OE.Plat-Appl Phase 1 A.Resp-Appl OE.Resp-Appl Phase 1 P.Process-TOE O.Identification Phase 2 – 3 optional Phase 4 A.Process-Sec-IC OE.Process-Sec-IC Phase 5 – 6 optional Phase 4 T.Leak-Inherent O.Leak-Inherent T.Phys-Probing O.Phys-Probing T.Malfunction O.Malfunction T.Phys-Manipulation O.Phys-Manipulation T.Leak-Forced O.Leak-Forced T.Abuse-Func O.Abuse-Func T.RND O.RND T.Mem-Access O.Mem-Access P.Add-Functions O.Add-Functions A.Key-Function OE.Plat-Appl OE.Resp-Appl Table 3: Security Objectives versus Assumptions, Threats or Policies The justification related to the assumption “Usage of Hardware Platform (A.Plat-Appl)” is as follows: Since OE.Plat-Appl requires the Smartcard Embedded Software developer to implement those measures assumed in A.Plat-Appl, the assumption is covered by the objective. The justification related to the assumption “Treatment of User Data (A.Resp-Appl)” is as follows: Since OE.Resp-Appl requires the developer of the Smartcard Embedded Software to implement measures as assumed in A.Resp-Appl, the assumption is covered by the objective. The justification related to the organisational security policy “Protection during TOE Development and Production (P.Process-TOE)” is as follows: CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 34 of 71 O.Identification requires that the TOE has to support the possibility of a unique identification. The unique identification can be stored on the TOE. Since the unique identification is generated by the production environment the production environment must support the integrity of the generated unique identification. The technical and organisational security measures that ensure the security of the development environment and production environment are evaluated based on the assurance measures that are part of the evaluation. For a list of material produced and processed by the TOE Manufacturer refer to paragraph 46 (page 19). All listed items and the associated development and production environments are subject of the evaluation. Therefore, the organisational security policy P.Process-TOE is covered by this objective, as far as organisational measures are concerned. The justification related to the assumption “Protection during Packaging, Finishing and Personalisation (A.Process-Sec-IC)” is as follows: Since OE.Process-Sec-IC requires the Composite Product Manufacturer to implement those measures assumed in A.Process-Sec-IC, the assumption is covered by this objective. The justification related to the threats “Inherent Information Leakage (T.Leak-Inherent)”, “Physical Probing (T.Phys-Probing)”, “Malfunction due to Environmental Stress (T.Malfunction)”, “Physical Manipulation (T.Phys-Manipulation)”, “Forced Information Leakage (T.Leak-Forced)“, “Abuse of Functionality (T.Abuse-Func)” and “Deficiency of Random Numbers (T.RND)” is as follows: For all threats the corresponding objectives are stated in a way, which directly corresponds to the description of the threat. It is clear from the description of each objective, that the corresponding threat is removed if the objective is valid. More specifically, in every case the ability to use the attack method successfully is countered, if the objective holds. The justification related to the threat “Memory Access Violation (T.Mem-Access)” is as follows: According to O.Mem-Access the TOE must enforce the partitioning of memory areas so that access of software to memory areas is controlled. Any restrictions are to be defined by the Smartcard Embedded Software. Thereby security violations caused by accidental or deliberate access to restricted data (which may include code) can be prevented (refer to T.Mem-Access). The threat T.Mem-Access is therefore removed if the objective is met. The clarification of “Usage of Hardware Platform (OE.Plat-Appl)” makes clear that it is up to the Smartcard Embedded Software to implement the memory management scheme by appropriately administrating the TSF. This is also expressed both in T.Mem-Access and O.Mem-Access. The TOE shall provide access control functions as a means to be used by the Smartcard Embedded Software. This is further emphasised by the clarification of “Treatment of User Data (OE.Resp-Appl)” which reminds that the Smartcard Embedded Software must not undermine the restrictions it defines. Therefore, the clarifications contribute to the coverage of the threat T.Mem-Access. The justification related to the security objective “Additional Specific Security Functionality (O.Add-Functions)” is as follows: Since O.Add-Functions requires the TOE to implement exactly the same specific security functionality as required by P.Add-Functions, the organisational security policy is covered by the objective. Nevertheless the security objectives O.Leak-Inherent, O.Phys-Probing, O.Malfunction, O.Phys- Manipulation and O.Leak-Forced define how to implement the specific security functionality required by P.Add-Functions. (Note that these objectives support that the specific security functionality is provided in a secure way as expected from P.Add-Functions.) Especially O.Leak-Inherent and O.Leak-Forced refer to the protection of confidential data (User Data or TSF data) in general. User Data are also processed by the specific security functionality required by P.Add-Functions. Compared to Smartcard IC Platform Protection Profile a clarification has been made for the security objective “Usage of Hardware Platform (OE.Plat-Appl)”: If required the Smartcard CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 35 of 71 Embedded Software shall use these cryptographic services of the TOE and their interface as specified. In addition, the Smartcard Embedded Software must implement functions which perform operations on keys (if any) in such a manner that they do not disclose information about confidential data. The non disclosure due to leakage A.Key-Function attacks is included in this objective OE.Plat-Appl. This addition ensures that the assumption A.Plat-Appl is still covered by the objective OE.Plat-Appl although additional functions are being supported according to O.Add-Functions. Compared to Smartcard IC Platform Protection Profile a clarification has been made for the security objective “Treatment of User Data (OE.Resp-Appl)”: By definition cipher or plain text data and cryptographic keys are User Data. So, the Smartcard Embedded Software will protect such data if required and use keys and functions appropriately in order to ensure the strength of cryptographic operation. Quality and confidentiality must be maintained for keys that are imported and/or derived from other keys. This implies that appropriate key management has to be realised in the environment. That is expressed by the assumption A.Key—Function which is covered from OE.Resp–Appl. These measures make sure that the assumption A.Resp-Appl is still covered by the security objective OE.Resp-Appl although additional functions are being supported according to P.Add-Functions. The justification of the additional policy and the additional assumption show that they do not contradict to the rationale already given in the Protection Profile for the assumptions, policy and threats defined there. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 36 of 71 5 EXTENDED COMPONENTS DEFINITION This chapter 5 Extended Components Definition contains the following sections: 5.1 Definition of the family FCS_RNG 5.2 Definition of the Family FMT_LIM 5.3 Definition of the Family FAU_SAS 5.1 Definition of the Family FCS_RNG To define the IT security functional requirements of the TOE an additional family (FCS_RNG) of the Class FCS (cryptographic support) is defined here. This family describes the functional requirements for random number generation used for cryptographic purposes. FCS_RNG Generation of Random Numbers Family behaviour This family defines quality requirements for the generation of random numbers which are intended to be use for cryptographic purposes. Component levelling: FCS_RNG.1 Generation of random numbers requires that random numbers meet a defined quality metric. Management: FCS_RNG.1 There are no management activities foreseen. Audit: FCS_RNG.1 There are no actions defined to be auditable. FCS_RNG.1 Random number generation Hierarchical to: No other components. Dependencies: No dependencies. FCS_RNG.1.1 The TSF shall provide a [selection: physical, non-physical true, deterministic, hybrid] random number generator that implements: [assignment: list of security capabilities]. FCS_RNG.1.2 The TSF shall provide random numbers that meet [assignment: a defined quality metric]. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 37 of 71 5.2 Definition of the Family FMT_LIM To define the IT security functional requirements of the TOE an additional family (FMT_LIM) of the Class FMT (Security Management) is defined here. This family describes the functional requirements for the Test Features of the TOE. The new functional requirements were defined in the class FMT because this class addresses the management of functions of the TSF. The examples of the technical mechanism used in the TOE appropriate to address the specific issues of preventing the abuse of functions by limiting the capabilities of the functions and by limiting their availability. The family “Limited capabilities and availability (FMT_LIM)” is specified as follows. FMT_LIM Limited capabilities and availability Family behaviour This family defines requirements that limit the capabilities and availability of functions in a combined manner. Note that FDP_ACF restricts the access to functions whereas the component Limited Capability of this family requires the functions themselves to be designed in a specific manner. Component levelling: FMT_LIM.1 Limited capabilities requires that the TSF is built to provide only the capabilities (perform action, gather information) necessary for its genuine purpose. FMT_LIM.2 Limited availability requires that the TSF restrict the use of functions (refer to Limited capabilities (FMT_LIM.1)). This can be achieved, for instance, by removing or by disabling functions in a specific phase of the TOE’s life-cycle. Management: FMT_LIM.1, FMT_LIM.2 There are no management activities foreseen. Audit: FMT_LIM.1, FMT_LIM.2 There are no actions defined to be auditable. The TOE Functional Requirement “Limited capabilities (FMT_LIM.1)” is specified as follows. FMT_LIM.1 Limited capabilities Hierarchical to: No other components. FMT_LIM.1.1 The TSF shall be designed and implemented in a manner that limits their capabilities so that in conjunction with “Limited availability (FMT_LIM.2)” CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 38 of 71 the following policy is enforced [assignment: Limited capability and availability policy]. Dependencies: FMT_LIM.2 Limited availability. The TOE Functional Requirement “Limited availability (FMT_LIM.2)” is specified as follows. FMT_LIM.2 Limited availability Hierarchical to: No other components. FMT_LIM.2.1 The TSF shall be designed in a manner that limits their availability so that in conjunction with “Limited capabilities (FMT_LIM.1)” the following policy is enforced [assignment: Limited capability and availability policy]. Dependencies: FMT_LIM.1 Limited capabilities. Application note: The functional requirements FMT_LIM.1 and FMT_LIM.2 assume that there are two types of mechanisms (limited capabilities and limited availability) which together shall provide protection in order to enforce the policy. This also allows that (i) the TSF is provided without restrictions in the product in its user environment but its capabilities are so limited that the policy is enforced or conversely (ii) the TSF is designed with high functionality but is removed or disabled in the product in its user environment. The combination of both requirements shall enforce the policy. 5.3 Definition of the Family FAU_SAS To define the security functional requirements of the TOE an additional family (FAU_SAS) of the Class FAU (Security Audit) is defined here. This family describes the functional requirements for the storage of audit data. It has a more general approach than FAU_GEN, because it does not necessarily require the data to be generated by the TOE itself and because it does not give specific details of the content of the audit records. The family “Audit data storage (FAU_SAS)” is specified as follows. FAU_SAS Audit data storage Family behaviour This family defines functional requirements for the storage of audit data. Component levelling CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 39 of 71 FAU_SAS.1 Requires the TOE to provide the possibility to store audit data. Management: FAU_SAS.1 There are no management activities foreseen. Audit: FAU_SAS.1 There are no actions defined to be auditable. FAU_SAS.1 Audit storage Hierarchical to: No other components. FAU_SAS.1.1 The TSF shall provide [assignment: list of subjects] with the capability to store [assignment: list of audit information] in the [assignment: type of persistent memory]. Dependencies: No dependencies. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 40 of 71 6 IT SECURITY REQUIREMENTS This chapter 6 IT Security Requirements contains the following sections: 6.1 Security Functional Requirements for the TOE 6.2 Security Assurance Requirements for the TOE 6.3 Security Requirements Rationale 6.1 Security Functional Requirements for the TOE In order to define the Security Functional Requirements the Part 2 of the Common Criteria was used. However, some Security Functional Requirements have been refined. The refinements are described below the associated SFR. The operations completed in the ST are marked in italic font. Malfunctions The TOE shall meet the requirement “Limited fault tolerance (FRU_FLT.2)” as specified below. FRU_FLT.2 Limited fault tolerance Hierarchical to: FRU_FLT.1 FRU_FLT.2.1 The TSF shall ensure the operation of all the TOE’s capabilities when the following failures occur: exposure to operating conditions which are not detected according to the requirement Failure with preservation of secure state (FPT_FLS.1) . Dependencies: FPT_FLS.1 Failure with preservation of secure state Refinement: The term “failure” above means “circumstances”. The TOE prevents failures for the “circumstances” defined above. The TOE shall meet the requirement “Failure with preservation of secure state (FPT_FLS.1)” as specified below. FPT_FLS.1 Failure with preservation of secure state Hierarchical to: No other components. FPT_FLS.1.1 The TSF shall preserve a secure state when the following types of failures occur: exposure to operating conditions which may not be tolerated according to the requirement Limited fault tolerance (FRU_FLT.2) and where therefore a malfunction could occur. Dependencies: No dependencies Refinement: The term “failure” above also covers “circumstances”. The TOE prevents failures for the “circumstances” defined above. Application note: The secure state is maintained by TOE’s detectors. The TOE’s detectors are monitoring the failure occurs. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 41 of 71 Abuse of Functionality The TOE shall meet the requirement “Limited capabilities (FMT_LIM.1)” as specified below(Common Criteria Part 2 extended). FMT_LIM.1 Limited capabilities Hierarchical to: No other components. FMT_LIM.1.1 The TSF shall be designed in a manner that limits their capabilities so that in conjunction with “Limited availability (FMT_LIM.2)” the following policy is enforced: Deploying Test Features after TOE Delivery does not allow User Data to be disclosed or manipulated, TSF data to be disclosed or manipulated, software to be reconstructed and no substantial information about construction of TSF to be gathered which may enable other attacks. Dependencies: FMT_LIM.2 Limited availability. The TOE shall meet the requirement “Limited availability (FMT_LIM.2)” as specified below (Common Criteria Part 2 extended). FMT_LIM.2 Limited availability Hierarchical to: No other components. FMT_LIM.2.1 The TSF shall be designed in a manner that limits their availability so that in conjunction with “Limited capabilities (FMT_LIM.1)” the following policy is enforced: Deploying Test Features after TOE Delivery does not allow User Data to be disclosed or manipulated, TSF data to be disclosed or manipulated, software to be reconstructed and no substantial information about construction of TSF to be gathered which may enable other attacks. Dependencies: FMT_LIM.1 Limited capabilities. The TOE shall meet the requirement “Audit storage (FAU_SAS.1)” as specified below (Common Criteria Part 2 extended). FAU_SAS.1 Audit storage Hierarchical to: No other components. FAU_SAS.1.1 The TSF shall provide the test process before TOE Delivery with the capability to store the Initialisation Data and/or Prepersonalisation Data and/or supplements of the Smartcard Embedded Software in a Test ROM area. Dependencies: No dependencies. Application Note: The integrity and uniqueness of the unique identification of the TOE must be supported by the development, production and test environment. Physical Manipulation and Probing The TOE shall meet the requirement “Resistance to physical attack (FPT_PHP.3)” as specified below. FPT_PHP.3 Resistance to physical attack Hierarchical to: No other components. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 42 of 71 FPT_PHP.3.1 The TSF shall resist physical manipulation and physical probing to the TSF by responding automatically such that the SFRs are always enforced. Dependencies: No dependencies. Refinement: The TSF will implement appropriate mechanisms to continuously counter physical manipulation and physical probing. Due to the nature of these attacks (especially manipulation) the TSF can by no means detect attacks on all of its elements. Therefore, permanent protection against these attacks is required ensuring that security functional requirements are enforced. Hence, “automatic response” means here (i) assuming that there might be an attack at any time and (ii) countermeasures are provided at any time. Application Note: This requirement is achieved by security feature as the Active shield must be removed and bypassed in order to perform physical intrusive attacks. The TOE makes a reset or FIQ occurs to stops operation if a physical manipulation or physical probing attack is detected. And also Static Address/Data scrambling for bus and memory & Synthesizable processor core make the reverse-engineering of the TOE layout unpractical. So these functionalities meet the security functional requirement of FPT_PHP.3: Resistance to physical attack. Leakage The TOE shall meet the requirement “Basic internal transfer protection (FDP_ITT.1)” as specified below. FDP_ITT.1 Basic internal transfer protection Hierarchical to: No other components. FDP_ITT.1.1 The TSF shall enforce the Data Processing Policy to prevent the disclosure of user data when it is transmitted between physically-separated parts of the TOE. Dependencies: [FDP_ACC.1 Subset access control, or FDP_IFC.1 Subset information flow control] Refinement: The different memories, the CPU and other functional units of the TOE (e.g. a cryptographic co-processor) are seen as physically-separated parts of the TOE. The TOE shall meet the requirement “Basic internal TSF data transfer protection (FPT_ITT.1)” as specified below. FPT_ITT.1 Basic internal TSF data transfer protection Hierarchical to: No other components. FPT_ITT.1.1 The TSF shall protect TSF data from disclosure when it is transmitted between separate parts of the TOE. Dependencies: No dependencies. Refinement: The different memories, the CPU and other functional units of the TOE (e.g. a cryptographic co-processor) are seen as separated parts of the TOE. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 43 of 71 This requirement is equivalent to FDP_ITT.1 above but refers to TSF data instead of User Data. Therefore, it should be understood as to refer to the same Data Processing Policy defined under FDP_IFC.1 below. The TOE shall meet the requirement “ Subset information flow control (FDP_IFC.1)”as specified below: FDP_IFC.1 Subset information flow control Hierarchical to: No other components. FDP_IFC.1.1 The TSF shall enforce the Data Processing Policy on all confidential data when they are processed or transferred by the TOE or by the Security IC Embedded Software. Dependencies: FDP_IFF.1 Simple security attributes The following Security Function Policy (SFP) Data Processing Policy is defined for the requirement “ Subset information flow control (FDP_IFC.1)”: User Data and TSF data shall not be accessible from the TOE except when the Security IC Embedded Software decides to communicate the User Data via an external interface. The protection shall be applied to confidential data only but without the distinction of attributes controlled by the Security IC Embedded Software. Random Numbers (DTRNG) The TOE shall meet the requirement “Quality metric for random numbers (FCS_RNG.1)” as specified below (Common Criteria Part 2 extended). FCS_RNG.1 Random number generation Hierarchical to: No other components. FCS_RNG.1.1 The TSF shall provide a physical random number generator that implements total failure test of the random source. FCS_RNG.1.2 The TSF shall provide random numbers together with a post processing described in DTRNG application note and DTRNG library that meet the “standard” level of ANSSI requirements (French metric).In addtition, The TSF shall provide random numbers that meet AIS 31 version 1 Functional Classes and Evaluation Methodology for Physical Random Number Generators, 25 September 2001 , Class P2. Dependencies: No dependencies. Application Note: The DTRNG library comprises some functions that performs statistical test on the TRNG output in order to ensure that the TRNG is working properly. If test is fails the function return an error value and the TRNG is shuttled down. Those functions are described in DTRNG Application note. Memory Access Control Usage of multiple applications in one Smartcard often requires separating code and data in order to prevent that one application can access code and/or data of another application. To support this the TOE provides Area based Memory Access Control. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 44 of 71 The security service being provided is described in the Security Function Policy (SFP) Memory Access Control Policy. The security functional requirement “Subset access control (FDP_ACC.1)” requires that this policy is in place and defines the scope were it applies. The security functional requirement “Security attribute based access control (FDP_ACF.1)” defines addresses security attribute usage and characteristics of policies. It describes the rules for the function that implements the Security Function Policy (SFP) as identified in FDP_ACC.1. The decision whether an access is permitted or not is taken based upon attributes allocated to the software. The user software defines the attributes and memory areas. The corresponding permission control information is evaluated “on-the-fly” by the hardware so that access is granted/effective or denied/inoperable. The security functional requirement “Static attribute initialization (FMT_MSA.3)” ensures that the default values of security attributes are appropriately either permissive or restrictive in nature. Alternative values can be specified by any subject provided that the Memory Access Control Policy allows that. This is described by the security functional requirement “Management of security attributes (FMT_MSA.1)”. The attributes are determined during TOE manufacturing (FMT_MSA.3) or set at run-time (FMT_MSA.1). From TOE´s point of view the different roles in the user software can be distinguished according to the memory based access control. However the definition of the roles belongs to the user software. The following Security Function Policy (SFP) Memory Access Control Policy is defined for the requirement “Security attribute based access control (FDP_ACF.1)”: Memory Access Control Policy The TOE shall control read, write, delete, execute accesses of software running at between two different modes (privilege and user mode) on data including code stored in memory areas. The TOE shall restrict the ability to define, to change or at least to finally accept the applied rules (as mentioned in FDP_ACF.1) to software with privilege mode). The TOE shall meet the requirement “Subset access control (FDP_ACC.1)” as specified below. FDP_ACC.1 Subset access control Hierarchical to: No other components. FDP_ACC.1.1 The TSF shall enforce the Memory Access Control Policy on all subjects (software with privilege mode and user mode), all objects (data including code stored in memories) and all the operations defined in the Memory Access Control Policy. Subjects are software codes in Privilege and User mode. Object are data stored in ROM, RAM and FLASH memories. Dependencies: FDP_ACF.1 Security attribute based access control The TOE shall meet the requirement “Security attribute based access control (FDP_ACF.1)” as specified below. FDP_ACF.1 Security attribute based access control The attributes are all the operations related to the data stored in memories, which are the read, write, delete and execute operations. Hierarchical to: No other components. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 45 of 71 FDP_ACF.1.1 The TSF shall enforce the Memory Access Control Policy to objects based on the memory area where the software is executed from and/or the memory area where the access is performed to and/or the operation to be performed. FDP_ACF.1.2 The TSF shall enforce the following rules to determine if an operation among controlled subjects and controlled objects is allowed: evaluate the corresponding permission control information before the access so that accesses to be denied can not be utilised by the subject attempting to perform the operation. FDP_ACF.1.3 The TSF shall explicitly authorise access of subjects to objects based on the following additional rules: none. FDP_ACF.1.4 The TSF shall explicitly deny access of subjects to objects based on the following additional rules: none. Dependencies: FDP_ACC.1 Subset access control FMT_MSA.3 Static attribute initialisation The TOE shall meet the requirement “Static attribute initialisation (FMT_MSA.3)” as specified below. FMT_MSA.3 Static attribute initialisation Hierarchical to: No other components. FMT_MSA.3.1 The TSF shall enforce the Memory Access Control Policy to provide well defined default values for security attributes that are used to enforce the SFP. FMT_MSA.3.2 The TSF shall allow any subject (provided that the Memory Access Control Policy is enforced and the necessary access is therefore allowed) to specify alternative initial values to override the default values when an object or information is created. Dependencies: FMT_MSA.1 Management of security attributes FMT_SMR.1 Security roles The TOE shall meet the requirement “Management of security attributes (FMT_MSA.1)” as specified below: FMT_MSA.1 Management of security attributes Hierarchical to: No other components. FMT_MSA.1.1 The TSF shall enforce the Memory Access Control Policy to restrict the ability to change default, modify or delete the security attributes permission control information to running at privilege mode. Dependencies: [FDP_ACC.1 Subset access control or FDP_IFC.1 Subset information flow control] FMT_SMF.1 Specification of management functions FMT_SMR.1 Security roles The TOE shall meet the requirement “Specification of management functions (FMT_SMF.1)” as specified below: FMT_SMF.1 Specification of management functions Hierarchical to: No other components CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 46 of 71 FMT_SMF.1.1 The TSF shall be capable of performing the following security management functions: access the control registers of the MPU. Dependencies: No dependencies Cryptographic Support FCS_COP.1 Cryptographic operation requires, a cryptographic operation to be performed in accordance with a specified algorithm and with a cryptographic key of specified sizes. The specified algorithm and cryptographic key sizes can be based on an assigned standard. The following additional specific security functionality is implemented in the TOE:  Triple Data Encryption Standard (3DES) with 112bit or 168bit key size,  Advanced Encryption Standard(AES) with 128 bit, 192bit and 256bit key size.  Rivest-Shamir-Adleman (RSA) public key asymmetric cryptography, with key size 1280-bit up to 4096-bit with a granularity of 2 bits (optional)  Elliptic Curve Cryptography (ECC) (optional) Note: The TOE can be delivered without the RSA/ECC crypto library. In this case the TOE does not provide the Additional Specific Security Functionality Rivest-Shamir-Adleman Cryptography and Elliptic Curve Cryptography (ECC) and Secure Hash Algorithm (SHA) Triple-DES Operation The Triple DES (3DES) operation of the TOE shall meet the requirement “Cryptographic operation (FCS_COP.1)” as specified below. FCS_COP.1/3DES Cryptographic operation Hierarchical to: No other components. FCS_COP.1.1/3DES The TSF shall perform encryption and decryption in accordance with a specified cryptographic algorithm Triple Data Encryption Standard (3DES) - ECB mode and cryptographic key sizes 112 bit or 168 bit key size that meet the following standards: [FIPS SP800-67], chapter 2 and 3. TOE implements 3DES with key option 1 and 2 with ECB mode. Dependencies: [FDP_ITC.1 Import of user data without security attributes or FDP_ITC.2 Import of user data with security attributes, or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4 Cryptographic key destruction AES Operation The AES operation of the TOE shall meet the requirement “Cryptographic operation (FCS_COP.1)” as specified below. FCS_COP.1/AES Cryptographic operation Hierarchical to: No other components. FCS_COP.1.1/AES The TSF shall perform encryption and decryption in accordance with a specified cryptographic algorithm Advanced Encryption Standard (AES) - ECB mode and cryptographic key sizes 128bit, 192bit or 256bit key size that meet the following standard: [PIBS197], chapter 5. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 47 of 71 Dependencies: [FDP_ITC.1 Import of user data without security attributes or FDP_ITC.2 Import of user data with security attributes or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4 Cryptographic key destruction Rivest-Shamir-Adleman (RSA) Operation (optional) The RSA/ECC cryptographic library of the TOE shall meet the requirement “Cryptographic operation (FCS_COP.1)” as specified below. FCS_COP.1/RSA Cryptographic operation Hierarchical to: No other components FCS_COP.1.1/RSA The TSF shall perform the modular exponentiation part of RSA signature generation and verification in accordance with a specified cryptographic algorithm Rivest-Shamir-Adleman (RSA:standard RSA and RSA-CRT) and cryptographic key sizes from 1280-bit up to 4096-bit with 2-bit granularity that meet the following standard: [ISO/IEC14888-2:2008]] section 6.2 and 6.3. Note 1: In context of signature generation only the modular exponentiation, i.e. only Step 2 of [ISO14888-2:2008], section 6.2 and in addition the check of the message's length are implemented. Especially the proper use of a format mechanism (including the related hash algorithm) is in the responsibility of the embedded software developer. Note 2: In context of signature verification only the modular exponentiation, i.e. only the part asking to compute G* = S^v mod n in Step 1 of [ISO/IEC14888-2:2008], section 6.3 is implemented. Especially the proper check of a signatures format (including the related hash algorithm) is in the responsibility of the embedded software developer. Dependencies: [FDP_ITC.1 Import of user data without security attributes or FDP_ITC.2 Import of user data with security attributes, or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4 Cryptographic key destruction Rivest-Shamir-Adleman (RSA) Key Generation (optional) The RSA key generation for the RSA/ECC library shall meet the requirement “Cryptographic key generation (FCS_CKM.1)” as specified below. FCS_CKM.1/RSA Cryptographic key generation Hierarchical to: No other components FCS_CKM.1.1/RSA The TSF shall generate the RSA public/private key pair in accordance with the specified cryptographic key generation algorithm and with the specified cryptographic key size from 1280-bit up to 4096-bit with 2-bit granularity that meet the following standards: [ETSI TS 102 176-1], section 6.2.2.1 Key and parameter generation algorithm rsagen1. Dependencies: [FCS_CKM.2 Cryptographic key distribution or FCS_COP.1 Cryptographic operation] CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 48 of 71 FCS_CKM.4 Cryptographic key destruction Note 1) The RSA cryptographic key generation of the TOE generates two primes P and Q with the equal bit length, while the standard recommends to generate two primes P and Q such that 0.1 < |log_2(P)-log_2(Q)| < 30. Note 2) While the standard specifies that the private exponent D should be larger than the square root of the RSA modulus, i.e. D > sqrt(N), this verification is not performed by the RSA cryptographic key generation of the TOE. Note 3) The RSA cryptographic key generation of the TOE performs a number of Miller-Rabin tests to ensure that the probability that the generated prime candidate is not a prime is below 2^(-100). Elliptic Curve DSA Operation (optional) The ECC library of the TOE shall meet the requirement “Cryptographic operation (FCS_COP.1)” as specified below. FCS_COP.1/ECDSA Cryptographic operation Hierarchical to: No other components FCS_COP.1.1/ECDSA The TSF shall perform the signature generation/verification in accordance with the specified cryptographic algorithm ECDSA and cryptographic key sizes from 192-bit up to 521-bit that meet the following standard: [ANS X9.62] , section 7.3 Signing Process and section 7.4 Verifying Process. Dependencies: [FDP_ITC.1 Import of user data without security attributes or FDP_ITC.2 Import of user data with security attributes, or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4 Cryptographic key destruction Note1) The RSA/ECC library supports any valid curves over prime fields of size from 192-bit to 521-bit. However standard curves listed below whose security has been proven are in the scope of this evaluation. 1) [NIST curves]: Curves P-192, P-224, P-256, P-384, P-521 2) [Brainpool curves]: brainpoolP192r1, brainpoolP192t1, brainpoolP224r1, brainpoolP224t1, brainpoolP256r1, brainpoolP256t1, brainpoolP320r1, brainpoolP320t1, brainpoolP384r1, brainpoolP384t1, brainpoolP512r1, brainpoolP512t1, 3) [SEC-recommended curves]: secp192k1, secp192r1, secp224k1, secp224r1, secp256k1, secp256r1, secp384r1, secp521r1 Note2) The TOE offers the functionality of hash value computation using SHA-1, SHA-224, SHA-256, SHA-384 and SHA-512. However, only the functions related to SHA-224, SHA-256, SHA-384 and SHA-512 is in the scope of this evaluation and is intended to be used for signature generation and verification. Note that neither of the functions must be used to hash secret values. In addition, the user is responsible for the truncation or padding of the hash value as CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 49 of 71 required by step e), section 7.3 and step c), section 7.4.1 of the standard cited above. Elliptic Curve DSA Key Generation (optional) The key generation for the ECC library shall meet the requirement “Cryptographic key generation (FCS_CKM.1)” as specified below. FCS_CKM.1/ECDSA Cryptographic key generation Hierarchical to: No other components FCS_CKM.1.1/ECDSA The TSF shall generate ECC cryptographic keys in accordance with the cryptographic key generation algorithm specified in [ANS X9.62] and with the cryptographic key sizes from 192-bit up to 521-bit that meet the following standard: [ANS X9.62] , section A.4.3 Elliptic Curve Key Generation. Dependencies: [FCS_CKM.2 Cryptographic key distribution or FCS_COP.1 Cryptographic operation] FCS_CKM.4 Cryptographic key destruction Note1) The RSA/ECC library supports any valid curves over prime fields of size from 192-bit to 521-bit. However standard curves listed below whose security has been proven are in the scope of this evaluation. 1) [NIST curves]: Curves P-192, P-224, P-256, P-384, P- 521, 2) [Brainpool curves]: brainpoolP192r1, brainpoolP192t1, brainpoolP224r1, brainpoolP224t1, brainpoolP256r1, brainpoolP256t1, brainpoolP320r1, brainpoolP320t1, brainpoolP384r1, brainpoolP384t1, brainpoolP512r1, brainpoolP512t1, 3) [SEC-recommended curves]: secp192k1, secp192r1, secp224k1, secp224r1, secp256k1, secp256r1, secp384r1, secp521r1 Elliptic Curve Diffie-Hellman (ECDH) Key Agreement (optional) The ECC library of the TOE shall meet the requirement “Cryptographic operation (FCS_COP.1)” as specified below. FCS_COP.1/ECDH Cryptographic operation Hierarchical to: No other components FCS_COP.1.1/ECDH The TSF shall perform the key exchange in accordance with the specified cryptographic algorithm ECDH and cryptographic key sizes from 192-bit up to 521-bit that meet the following standard: [ANS X9.63], section 5.4.1 Standard Diffie-Hellman primitive. Dependencies: [FDP_ITC.1 Import of user data without security attributes or FDP_ITC.2 Import of user data with security attributes, or FCS_CKM.1 Cryptographic key generation] FCS_CKM.4 Cryptographic key destruction Note1) The RSA/ECC library supports any valid curves over prime fields of size from 192-bit to 521-bit. However standard curves listed below CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 50 of 71 whose security has been proven are in the scope of this evaluation. 1) [NIST curves]: Curves P-192, P-224, P-256, P-384, P-521 2) [Brainpool curves]: brainpoolP192r1, brainpoolP192t1, brainpoolP224r1, brainpoolP224t1, brainpoolP256r1, brainpoolP256t1, brainpoolP320r1, brainpoolP320t1, brainpoolP384r1, brainpoolP384t1, brainpoolP512r1, brainpoolP512t1, 3)[SEC-recommended curves]: secp192k1, secp192r1, secp224k1, secp224r1, secp256k1, secp256r1, secp384r1, secp521r1 Note2) The implemented routines can be used with ephemeral or static private keys. The base point is assumed to be public. Note3) For full compatibility, the user is responsible to perform step 2 of [ANS X9.63], section 5.2.2.1, prior to using the ECDH_generate function. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 51 of 71 Secure Hash Algorithm (SHA) (optional) The Secure Hash Algorithm (SHA) of the TOE shall meet the requirement “Cryptographic operation (FCS_COP.1)” as specified below. FCS_COP.1/SHA Cryptographic operation Hierarchical to: No other components FCS_COP.1.1/SHA The TSF shall perform secure hash computation in accordance with a specified cryptographic algorithm SHA1, SHA224, SHA256, SHA384 and SHA512 and cryptographic key sizes none that meet the following standard: [FIPS PUB 180-3]. Note1) The TORNADO-E RSA/ECC library provides the functionalities for computation of hash values. The use of these functionalities for keyed hash operations like HMAC or similar, is not subject of this TOE and requires specific security improvements and DPA analysis by the operating system which is not part of the TOE. The SHA224, SHA256, SHA384 and SHA512 functionalities are intended to be used for ECDSA signature generation and verification. Dependencies: No dependencies Summary of Security Functional Requirements Security Functional Requirements Limited fault tolerance (FRU_FLT.2) Failure with preservation of secure state (FPT_FLS.1) Audit storage (FAU_SAS.1) Limited capabilities(FMT_LIM.1) Limited availability (FMT_LIM.2) Resistance to physical attack (FPT_PHP.3) Basic internal transfer protection (FDP_ITT.1) Basic internal TSF data transfer protection (FPT_ITT.1) Subset information flow control (FDP_IFC.1) Quality metric for random numbers (FCS_RNG.1) Table 4. Security Functional Requirements defined in Smart Card IC Protection Profile Security Functional Requirements Subset access control (FDP_ACC.1) Security attribute based access control (FDP_ACF.1) Static attribute initialization (FMT_MSA.3 ) Management of security attributes (FMT_MSA.1) Specification of management functions (FMT_SMF.1) Cryptographic operation (FCS_COP.1/RSA) (optional) Cryptographic key generation (FCS_CKM.1/ RSA) (optional) CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 52 of 71 Cryptographic operation (FCS_COP.1/3DES) Cryptographic operation (FCS_COP.1/AES) Cryptographic operation (FCS_COP.1/ECDSA) (optional) Cryptographic operation (FCS_COP.1/ECDH) (optional) Cryptographic key generation (FCS_CKM.1/ ECDSA) (optional) Cryptographic key generation (FCS_COP.1/SHA) (optional) Table 5. Augmented Security Functional Requirements 6.2 TOE Assurance Requirements The Security Target will be evaluated according to Security Target evaluation (Class ASE) The TOE Assurance Requirements for the evaluation of the TOE and its development and operating environment are those taken from the Evaluation Assurance Level 5 (EAL5) and augmented by the following components ALC_DVS.2 and AVA_VAN.5 corresponding to level “EAL5+”. All refinements from Protection Profile BSI-PP-0035 version 1.0 for the assurance requirements (ALC_DEL, ALC_DVS, ALC_CMS, ALC_CMC, ADV_ARV, ADV_FSP, ADV_IMP, ATE_COV, AGD_OPE, AGD_PRE and ADV_VAN) have to be taken into consideration. In particular the document [13] is used in the context of vulnerability analysis Class ADV: Development Architectural design (ADV_ARC.1) Functional Specification (ADV_FSP.5) Implementation Representation (ADV_IMP.1) TSF Internals (ADV_INT.2) TOE Design (ADV_TDS.4) Class AGD: Guidance documents activities Operational User Guidance (AGD_OPE.1) Preparative procedures (AGD_PRE.1) Class ALC: Life-cycle support CM Capabilities (ALC_CMC.4) CM Scope (ALC_CMS.5) Delivery (ALC_DEL.1) Development Security (AULCU_DVS.2) Life Cycle Definition (ALC_LCD.1) Tools and Techniques (ALC_TAT.2) Class ASE: Security Target evaluation Conformance claims (ASE_CCL.1) Extended components definition (ASE_ECD.1) ST introduction (ASE_INT.1) CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 53 of 71 Security objectives (ASE_OBJ.2) Derived security requirements (ASE_REQ.2) Security problem definition (ASE_SPD.1) TOE summary specification (ASE_TSS.1) Class ATE: Tests Coverage (ATE_COV.2) Depth (ATE_DPT.3) Functional Tests (ATE_FUN.1) Independent Testing (ATE_IND.2) Class AVA: Vulnerability assessment Vulnerability Analysis (AVA_VAN.5) 6.3 Security Requirements Rationale 6.3.1 Rationale for the Security Functional Requirements Table 6 below gives an overview, how the security functional requirements are combined to meet the security objectives. The detailed justification follows after the table. Objective TOE Security Functional and Assurance Requirements O.Leak-Inherent - FDP_ITT.1 “Basic internal transfer protection” - FPT_ITT.1 “Basic internal TSF data transfer protection” - FDP_IFC.1 “Subset information flow control” - AVA_VAN.5 “Advanced methodical vulnerability analysis” O.Phys-Probing - FPT_PHP.3 “Resistance to physical attack” O.Malfunction - FRU_FLT.2 “Limited fault tolerance - FPT_FLS.1 “Failure with preservation of secure state” - ADV_ARC.1 “Architectural Design with domain separation and non-bypassability” O.Phys-Manipulation - FPT_PHP.3 “Resistance to physical attack” O.Leak-Forced All requirements listed for O.Leak-Inherent - FDP_ITT.1, FPT_ITT.1, FDP_IFC.1, AVA_VAN.5 plus those listed for O.Malfunction and O.Phys-Manipulation - FRU_FLT.2, FPT_FLS.1, FPT_PHP.3, ADV_ARC.1 O.Abuse-Func - FMT_LIM.1 “Limited capabilities” - FMT_LIM.2 “Limited availability” plus those for O.Leak-Inherent, O.Phys-Probing, O.Malfunction, O.Phys-Manipulation, O.Leak-Forced - FDP_ITT.1, FPT_ITT.1, FDP_IFC.1, FPT_PHP.3, FRU_FLT.2, FPT_FLS.1, ADV_ARC.1 O.Identification - FAU_SAS.1 “Audit storage” CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 54 of 71 Objective TOE Security Functional and Assurance Requirements O.RND - FCS_RNG.1 “Quality metric for random numbers” plus those for O.Leak-Inherent, O.Phys-Probing, O.Malfunction, O.Phys-Manipulation, O.Leak-Forced - FDP_ITT.1, FPT_ITT.1, FDP_IFC.1, FPT_PHP.3, FRU_FLT.2, FPT_FLS.1, AVA_VAN.5, ADV_ARC.1 OE.Plat-Appl not applicable OE.Resp-Appl not applicable OE.Process-Sec-IC not applicable O.Mem-Access - FDP_ACC.1 “Subset access control” - FDP_ACF.1 “Security attribute based access control” - FMT_MSA.3 “Static attribute initialisation” - FMT_MSA.1 “Management of security attributes” - FMT_SMF.1 “Specification of Management Functions” O.Add-Functions - FCS_COP.1 ”Cryptographic operation“ - FCS_CKM.1 /ECDSA (optional) - FCS_CKM.1 /RSA (optional) Table 6: Security Requirements versus Security Objectives The justification related to the security objective “Protection against Inherent Information Leakage (O.Leak-Inherent)” is as follows: The refinements of the security functional requirements FPT_ITT.1 and FDP_ITT.1 together with the policy statement in FDP_IFC.1 explicitly require the prevention of disclosure of secret data (TSF data as well as User Data) when transmitted between separate parts of the TOE or while being processed. This includes that attackers cannot reveal such data by measurements of emanations, power consumption or other behaviour of the TOE while data are transmitted between or processed by TOE parts. Of course this has also to be supported by the Security IC Embedded Software. For example timing attacks were possible if the processing time of algorithms implemented in the software would depend on the content of secret variables. The justification related to the security objective “Protection against Physical Probing (O.Phys-Probing)” is as follows: The scenario of physical probing as described for this objective is explicitly included in the assignment chosen for the physical tampering scenarios in FPT_PHP.3. Therefore, it is clear that this security functional requirement supports the objective. It is possible that the TOE needs additional support by the Security IC Embedded Software (e. g. to send data over certain buses only with appropriate precautions). In this case the combination of the Security IC Embedded Software together with FPT_PHP.3 is suitable to meet the objective. The justification related to the security objective “Protection against Malfunctions (O.Malfunction)” is as follows: The definition of this objective shows that it covers a situation, where malfunction of the TOE might be caused by the operating conditions of the TOE (while direct manipulation of the TOE is covered O.Phys-Manipulation). There are two possibilities in this situation: Either the CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 55 of 71 operating conditions are inside the tolerated range or at least one of them is outside of this range. The second case is covered by FPT_FLS.1, because it states that a secure state is preserved in this case. The first case is covered by FRU_FLT.2 because it states that the TOE operates correctly under normal (tolerated) conditions. To support this, the functions implementing FRU_FLT.2 and FPT_FLS.1 must work independently so that their operation can not affected by the Security IC Embedded Software (refer to the refinement). Therefore, there is no possible instance of conditions under O.Malfunction, which is not covered. The suitability of the implementation is subject of the evaluation of the assurance component ADV_ARC.1 The justification related to the security objective “Protection against Physical Manipulation (O.Phys-Manipulation)” is as follows: The scenario of physical manipulation as described for this objective is explicitly included in the assignment chosen for the physical tampering scenarios in FPT_PHP.3. Therefore, it is clear that this security functional requirement supports the objective. It is possible that the TOE needs additional support by the Embedded Software (for instance by implementing FDP_SDI.1 to check data integrity with the help of appropriate checksums). This support must be addressed in the Guidance Documentation. Together with this FPT_PHP.3 is suitable to meet the objective. The justification related to the security objective “Protection against Forced Information Leakage (O.Leak-Forced)“ is as follows: This objective is directed against attacks, where an attacker wants to force an information leakage, which would not occur under normal conditions. In order to achieve this the attacker has to combine a first attack step, which modifies the behaviour of the TOE (either by exposing it to extreme operating conditions or by directly manipulating it) with a second attack step measuring and analysing some output produced by the TOE. The first step is prevented by the same measures which support O.Malfunction and O.Phys-Manipulation, respectively. The requirements covering O.Leak-Inherent also support O.Leak-Forced because they prevent the attacker from being successful if he tries the second step directly. The justification related to the security objective “Protection against Abuse of Functionality (O.Abuse-Func)” is as follows: This objective states that abuse of functions (especially provided by the IC Dedicated Test Software, for instance in order to read secret data) must not be possible in Phase 7 of the life- cycle. There are two possibilities to achieve this: (i) They cannot be used by an attacker (i. e. its availability is limited) or (ii) using them would not be of relevant use for an attacker (i. e. its capabilities are limited) since the functions are designed in a specific way. The first possibility is specified by FMT_LIM.2 and the second one by FMT_LIM.1. Since these requirements are combined to support the policy, which is suitable to fulfil O.Abuse-Func, both security functional requirements together are suitable to meet the objective. Other security functional requirements which prevent attackers from circumventing the functions implementing these two security functional requirements (for instance by manipulating the hardware) also support the objective. The relevant objectives are also listed in Table 6. It was chosen to define FMT_LIM.1 and FMT_LIM.2 explicitly (not using Part 2 of the Common Criteria) for the following reason: Though taking components from the Common Criteria catalogue makes it easier to recognise functions, any selection from Part 2 of the Common Criteria would have made it harder for the reader to understand the special situation meant here. As a consequence, the statement of explicit security functional requirements was chosen to provide more clarity. The justification related to the security objective “TOE Identification (O.Identification)“ is as follows: Obviously the operations for FAU_SAS.1 are chosen in a way that they require the TOE to provide the functionality needed for O.Identification. The Initialisation Data (or parts of them) CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 56 of 71 are used for TOE identification. The technical capability of the TOE to store Initialisation Data and/or Pre-personalisation Data is provided according to FAU_SAS.1. It was chosen to define FAU_SAS.1 explicitly (not using a given security functional requirement from Part 2 of the Common Criteria) for the following reason: The security functional requirement FAU_GEN.1 in Part 2 of the CC requires the TOE to generate the audit data and gives details on the content of the audit records (for instance data and time). The possibility to use the functions in order to store security relevant data which are generated outside of the TOE, is not covered by the family FAU_GEN or by other families in Part 2. Moreover, the TOE cannot add time information to the records, because it has no real time clock. Therefore, the new family FAU_SAS was defined for this situation. The objective must be supported by organisational and other measures, which the TOE Manufacturer has to implement. These measures are a subset of those measures, which are examined during the evaluation of the assurance requirements of the classes AGD, ALC and ADO. The justification related to the security objective “Random Numbers (O.RND)” is as follows: Other security functional requirements, which prevent physical manipulation and malfunction of the TOE (see the corresponding objectives listed in the table) support this objective because they prevent attackers from manipulating or otherwise affecting the random number generator. Random numbers are often used by the Security IC Embedded Software to generate cryptographic keys for internal use. Therefore, the TOE must prevent the unauthorised disclosure of random numbers. Other security functional requirements which prevent inherent leakage attacks, probing and forced leakage attacks ensure the confidentiality of the random numbers provided by the TOE. Depending on the functionality of specific TOEs the Security IC Embedded Software will have to support the objective by providing runtime-tests of the random number generator. Together, these requirements allow the TOE to provide cryptographically good random numbers and to ensure that no information about the produced random numbers is available to an attacker. It was chosen to define FCS_RNG.1 explicitly, because Part 2 of the Common Criteria do not contain generic security functional requirements for Random Number generation. (Note, that there are security functional requirements in Part 2 of the Common Criteria, which refer to random numbers. However, they define requirements only for the authentication context, which is only one of the possible applications of random numbers.) The justification related to the security objective “Area based Memory Access Control (O.Mem- Access)” is as follows: The security functional requirement “Subset access control (FDP_ACC.1)” with the related Security Function Policy (SFP) “Memory Access Control Policy” exactly require the implementation of an area based memory access control, which is a requirement from O.Mem- Access. Therefore, FDP_ACC.1 with its SFP is suitable to meet the security objective. The security functional requirement “Static attribute initialisation (FMT_MSA.3)” requires that the TOE provides default values for the security attributes. Since the TOE is a hardware platform these default values are generated by the reset procedure. Therefore FMT_MSA.3 is suitable to meet the security objective O.Mem-Access. The security functional requirement “Management of security attributes (FMT_MSA.1)” requires that the ability to change the security attributes is restricted to privileged subject(s). It ensures that the access control required by O.Mem-Access can be realised using the functions provided by the TOE. Therefore FMT_MSA.1 is suitable to meet the security objective O.Mem_Access. Finally, the security functional requirement “Specification of Management Functions (FMT_SMF.1)” is used for the specification of the management functions to be provided by the CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 57 of 71 TOE as required by O.MEM_ACCESS. Therefore, FMT_SMF.1 is suitable to meet the security objective O.Mem_Access. The justification related to the security objective “Additional Specific Security Functionality (O.Add-Functions)” is as follows: The security functional requirement(s) “Cryptographic operation (FCS_COP.1)” exactly requires those functions to be implemented which are demanded by O.Add-Functions. FCS_CKM.1 supports the generation of ECC keys needed for this cryptographic operations (optional). Therefore, FCS_COP.1 and FCS_CKM.1 are suitable to meet the security objective. The justification related to the security objective “Protection during Packaging, Finishing and Personalisation (OE.Process-Sec-IC)” is as follows: The Composite Product Manufacturer has to use adequate measures to fulfil OE.Process-Sec-IC. Depending on the security needs of the application, the Security IC Embedded Software may have to support this for instance by using appropriate authentication mechanisms for personalisation functions. 6.3.2 Dependencies of Security Functional Requirements Table 7 below lists the security functional requirements defined in this Protection Profile, their dependencies and whether they are satisfied by other security requirements defined in this Protection Profile. The text following the table discusses the remaining cases. Security Functional Requirement Dependencies Fulfilled by security requirements FRU_FLT.2 FPT_FLS.1 Yes FPT_FLS.1 None No dependency FMT_LIM.1 FMT_LIM.2 Yes FMT_LIM.2 FMT_LIM.1 Yes FAU_SAS.1 None No dependency FPT_PHP.3 None No dependency FDP_ITT.1 FDP_ACC.1 or FDP_IFC.1 Yes FDP_IFC.1 FDP_IFF.1 See discussion below FPT_ITT.1 None No dependency FCS_RNG.1 None No dependency CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 58 of 71 Security Functional Requirement Dependencies Fulfilled by security requirements FCS_COP.1 /3DES FCS_CKM.4 Yes (by environment, see discussion below) FDP_ITC.1 or FDP_ITC.2 (if not FCS_CKM.1) or FCS_CKM.1 Yes (by environment, see discussion below) FCS_COP.1 /AES FCS_CKM.4 Yes (by environment, see discussion below) FDP_ITC.1 or FDP_ITC.2 (if not FCS_CKM.1) or FCS_CKM.1 Yes (by environment, see discussion below) FCS_COP.1 /RSA (optional) FCS_CKM.4 Yes (additionally it can be fulfilled by the environment, see discussion below) FDP_ITC.1 or FDP_ITC.2 (if not FCS_CKM.1) or FCS_CKM.1 Yes (by environment, see discussion below) FCS_COP.1 /ECDSA (optional) FCS_CKM.4 Yes (additionally it can be fulfilled by the environment, see discussion below) FDP_ITC.1 or FDP_ITC.2 (if not FCS_CKM.1) or FCS_CKM.1 Yes (by environment, see discussion below) FCS_COP.1 /ECDH (optional) FCS_CKM.4 Yes (additionally it can be fulfilled by the environment, see discussion below) FDP_ITC.1 or FDP_ITC.2 (if not FCS_CKM.1) or FCS_CKM.1 Yes (by environment, see discussion below) FDP_ACC.1 FDP_ACF.1 Yes FDP_ACF.1 FDP_ACC.1 FMT_MSA.3 Yes Yes FMT_MSA.3 FMT_MSA.1 FMT_SMR.1 Yes See discussion below FMT_MSA.1 FDP_ACC.1 or FDP_IFC.1 FMT_SMR.1 FMT_SMF.1 Yes See discussion below Yes FMT_SMF.1 None No dependency FCS_CKM.1 /RSA (optional) FCS_COP.1 or FCS_CKM.2 FCS_CKM.4 Yes FCS_CKM.1 /ECDSA (optional) FCS_COP.1 or FCS_CKM.2 FCS_CKM.4 Yes CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 59 of 71 Security Functional Requirement Dependencies Fulfilled by security requirements FCS_COP.1/SHA (optional) FDP_ITC.1 or FDP_ITC.2 Yes Table 7: Dependencies of the Security Functional Requirements Part 2 of the Common Criteria defines the dependency of FDP_IFC.1 (information flow control policy statement) on FDP_IFF.1 (Simple security attributes). The specification of FDP_IFF.1 would not capture the nature of the security functional requirement nor add any detail. As stated in the Data Processing Policy referred to in FDP_IFC.1 there are no attributes necessary. The security functional requirement for the TOE is sufficiently described using FDP_ITT.1 and its Data Processing Policy (FDP_IFC.1). Therefore the dependency is considered satisfied. In particular the security functional requirements providing resistance of the hardware against manipulations (e. g. FPT_PHP.3) support all other more specific security functional requirements (e. g. FCS_RNG.1) because they prevent an attacker from disabling or circumventing the latter. Together with the discussion of the dependencies above this shows that the security functional requirements build a mutually supportive whole. The functional requirements FCS_CKM.1 and FCS_CKM.4 which are dependent to FCS_COP.1/DES and FCS_COP.1/AES are not included in this Security Target since the TOE only provides an engine for encryption and decryption. But the Security IC Embedded Software may fulfill these requirements related to the needs of the implemented application. The dependent requirements of FCS_COP.1/DES and FCS_COP.1/AES concerning these functions shall be fulfilled by the environment (Security IC Embedded Software). The TOE provides the cryptographic key generation for RSA and ECDSA by the TOE (FCS_CKM.1/RSA, FCS_CKM.1/ECDSA), but it is up to the Smart Card Embedded Software’s security policy to adopt the cryptographic key generation by the TOE or use the cryptographic key generation by the Smart Card Embedded Software. The dependent requirements of FCS_COP.1/RSA and FCS_COP.1/ECDSA shall be fulfilled by the environment (Security IC Embedded Software). The functional requirement FCS_CKM.1 which is dependent to FCS_COP.1/ECDH is not included in this Security Target. But the Security IC Embedded Software may fulfill this requirement related to the needs of the implemented application. The dependent requirements of FCS_COP.1/ECDH concerning this function shall be fulfilled by the environment (Security IC Embedded Software). The functional requirement FCS_CKM.4 which is dependent to FCS_COP.1/RSA, FCS_COP.1/ECDH and FCS_COP.1/ECDSA are not included in this Security Target. But the Security IC Embedded Software may fulfill this requirement related to the needs of the implemented application. The dependent requirements of FCS_COP.1/RSA, FCS_COP.1/ECDH and FCS_COP.1/ECDSA concerning this function shall be fulfilled by the environment (Security IC Embedded Software). Since SHA is a keyless algorithm, the dependencies FCS_CKM.1 and FMT_CKM.4 are not required. The dependency FMT_SMR.1 introduced by the two components FMT_MSA.1 and FMT_MSA.3 is considered to be satisfied because the access control specified for the intended TOE is not role-based but enforced for each subject. Therefore, there is no need to identify roles in form of a security functional requirement FMT_SMR.1. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 60 of 71 6.3.3 Rationale for the Assurance Requirements The assurance level EAL5 and the augmentation with the requirements ALC_DVS.2, and AVA_VAN.5 were chosen in order to meet assurance expectations explained in the following paragraphs. An assurance level of EAL5 is required for this type of TOE since it is intended to defend against sophisticated attacks. This evaluation assurance level was selected since it is designed to permit a developer to gain maximum assurance from positive security engineering based on good commercial practices. In order to provide a meaningful level of assurance that the TOE provides an adequate level of defence against such attacks, the evaluators should have access to the low level design and source code. ALC_DVS.2 Sufficiency of Security Measures Development security is concerned with physical, procedural, personnel and other technical measures that may be used in the development environment to protect the TOE. In the particular case of a Security IC the TOE is developed and produced within a complex and distributed industrial process which must especially be protected. Details about the implementation, (e.g. from design, test and development tools as well as Initialization Data) may make such attacks easier. Therefore, in the case of a Security IC, maintaining the confidentiality of the design is very important. This assurance component is a higher hierarchical component to EAL5 (which only requires ALC_DVS.1). ALC_DVS.2 has no dependencies. AVA_VAN.5 Advanced Methodical Vulnerability Analysis Due to the intended use of the TOE, it must be shown to be highly resistant to penetration attacks. This assurance requirement is achieved by the AVA_VAN.5 component. Independent vulnerability analysis is based on highly detailed technical information. The main intent of the evaluator analysis is to determine that the TOE is resistant to penetration attacks performed by an attacker possessing high attack potential. AVA_VAN.5 has dependencies to ADV_ARC.1 “Security Architectural Design”, ADV_FSP.4 “Complete functional specification”, ADV_TDS.3 “Basic modular design”, ADV_IMP.1 “Implementation representation of the TSF”, AGD_OPE.1 “Operational user guidance”, AGD_PRE.1 “Preparative procedures”, and ATE_DPT.1 “Testing: Basic design”. All these dependencies are satisfied by EAL5. It has to be assumed that attackers with high attack potential try to attack Security ICs like smart cards used for digital signature applications or payment systems. Therefore, specifically AVA_VAN.5 was chosen in order to assure that even these attackers cannot successfully attack the TOE. 6.3.4 Security Requirements are Internally Consistent The discussion of security functional requirements and assurance components in the preceding sections has shown that mutual support and consistency are given for both groups of requirements. The arguments given for the fact that the assurance components are adequate for the functionality of the TOE also shows that the security functional requirements and assurance requirements support each other and that there are no inconsistencies between these groups. The security functional requirement FPT_PHP.3 makes it harder to manipulate data. This protects the primary assets and other security features or functionality which use these data. Though a manipulation of the TOE (refer to FPT_PHP.3) is not of great value for an attacker in itself, it can be an important step in order to threaten the primary assets. Therefore, the security CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 61 of 71 functional requirement FPT_PHP.3 is not only required to meet the security objective O.Phys-Manipulation. Instead it protects other security features or functions of both the TOE and the Security IC Embedded Software from being bypassed, deactivated or changed. In particular this may pertain to the security features or functions being specified using FDP_ITT.1, FPT_ITT.1, FPT_FLS.1, FMT_LIM.2, FCS_RNG.1, and those implemented in the Security IC Embedded Software. A malfunction of TSF (refer to FRU_FLT.2 and FPT_FLS.1) can be an important step in order to threaten the primary assets. Therefore, the security functional requirements FRU_FLT.2 and FPT_FLS.1 are not only required to meet the security objective O.Malfunction. Instead they protect other security features or functions of both the TOE and the Security IC Embedded Software from being bypassed, deactivated or changed. In particular this pertains to the security features or functions being specified using FDP_ITT.1, FPT_ITT.1, FMT_LIM.1, FMT_LIM.2, FCS_RNG.1, and those implemented in the Security IC Embedded Software. In a forced leakage attack the methods described in “Malfunction due to Environmental Stress” (refer to T.Malfunction) and/or “Physical Manipulation” (refer to T.Phys-Manipulation) are used to cause leakage from signals which normally do not contain significant information about secrets. Therefore, in order to avert the disclosure of primary assets it is important that the security functional requirements averting leakage (FDP_ITT.1, FPT_ITT.1) and those against malfunction (FRU_FLT.2 and FPT_FLS.1) and physical manipulation (FPT_PHP.3) are effective and bind well. The security features and functions against malfunction ensure correct operation of other security functions (refer to above) and help to avert forced leakage themselves in other attack scenarios. The security features and functions against physical manipulation make it harder to manipulate the other security functions (refer to above). Physical probing (refer to FPT_PHP.3) shall directly avert the disclosure of primary assets. In addition, physical probing can be an important step in other attack scenarios if the corresponding security features or functions use secret data. For instance the security functional requirement FMT_LIM.2 may use passwords. Therefore, the security functional requirement FPT_PHP.3 (against probing) help to protect other security features or functions including those being implemented in the Security IC Embedded Software. Details depend on the implementation. Leakage (refer to FDP_ITT.1, FPT_ITT.1) shall directly avert the disclosure of primary assets. In addition, inherent leakage and forced leakage (refer to above) can be an important step in other attack scenarios if the corresponding security features or functions use secret data. For instance the security functional requirement FMT_LIM.2 may use passwords. Therefore, the security functional requirements FDP_ITT.1 and FPT_ITT.1 help to protect other security features or functions implemented in the Security IC Embedded Software (FDP_ITT.1) or provided by the TOE (FPT_ITT.1). Details depend on the implementation. According to the assumption Usage of Hardware Platform (A.Plat-Appl) the Security IC Embedded Software will correctly use the functions provided by the TOE. Hereby the User Data are treated as required to meet the requirements defined for the specific application context (refer to Treatment of User Data (A.Resp-Appl)). However, the TOE may implement additional functions. This can be a risk if their interface can not completely be controlled by the Security IC Embedded Software. Therefore, the security functional requirements FMT_LIM.1 and FMT_LIM.2 are very important. They ensure that appropriate control is applied to the interface of these functions (limited availability) and that these functions, if being usable, provide limited capabilities only. The combination of the security functional requirements FMT_LIM.1 and FMT_LIM.2 ensures that (especially after TOE Delivery) these additional functions can not be abused by an attacker to (i) disclose or manipulate User Data, (ii) to manipulate (explore, bypass, deactivate or change) security features or functions of the TOE or of the Security IC Embedded Software or (iii) to enable an attack. Hereby the binding between these two security functional requirements is very important: CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 62 of 71 The security functional requirement Limited Capabilities (FMT_LIM.1) must close gaps which could be left by the control being applied to the function’s interface (Limited Availability (FMT_LIM.2)). Note that the security feature or function which limits the availability can be bypassed, deactivated or changed by physical manipulation or a malfunction caused by an attacker. Therefore, if Limited Availability (FMT_LIM.2) is vulnerable1, it is important to limit the capabilities of the functions in order to limit the possible benefit for an attacker. The security functional requirement Limited Availability (FMT_LIM.2) must close gaps which could result from the fact that the function’s kernel in principle would allow to perform attacks. The TOE must limit the availability of functions which potentially provide the capability to disclose or manipulate User Data, to manipulate security features or functions of the TOE or of the Security IC Embedded Software or to enable an attack. Therefore, if an attacker could benefit from using such functions1F, it is important to limit their availability so that an attacker is not able to use them. No perfect solution to limit the capabilities (FMT_LIM.1) is required if the limited availability (FMT_LIM.2) alone can prevent the abuse of functions. No perfect solution to limit the availability (FMT_LIM.2) is required if the limited capabilities (FMT_LIM.1) alone can prevent the abuse of functions. Therefore, it is correct that both requirements are defined in a way that they together provide sufficient security. It is important to avert malfunctions of TSF and of security functions implemented in the Security IC Embedded Software (refer to above). There are two security functional requirements which ensure that malfunctions can not be caused by exposing the TOE to environmental stress. First it must be ensured that the TOE operates correctly within some limits (Limited fault tolerance (FRU_FLT.2)). Second the TOE must prevent its operation outside these limits (Failure with preservation of secure state (FPT_FLS.1)). Both security functional requirements together prevent malfunctions. The two functional requirements must define the “limits”. Otherwise there could be some range of operating conditions which is not covered so that malfunctions may occur. Consequently, the security functional requirements Limited fault tolerance (FRU_FLT.2) and Failure with preservation of secure state (FPT_FLS.1) are defined in a way that they together provide sufficient security. The security functional requirements required to meet the security objectives O.Leak-Inherent, O.Phys-Probing, O.Malfunction, O.Phys-Manipulation and O.Leak-Forced protect the cryptographic algorithms (FCS_COP.1) and the cryptographic key generations (FCS_CKM.1). Therefore these security functional requirements support the secure implementation and operation of FCS_COP.1 and FCS_CKM.1. Parts of the Smartcard IC Embedded Software may cause security violations by accidentally or deliberately accessing restricted data (which may include code). In order to avert the memory access violation it is important to the security functional requirement defining the scope where the Memory Access Policy is applied (FDP_ACC.1) and the security functional requirement defining the Memory Access Policy(FDP_ACF.1), and the security functional requirement ensuring the default value of security attribute(FMT_MSA.3) and the security functional requirement managing security attribute ( FMT_MSA.1) and the security functional requirement performing security management function(FMT_SMF.1) are effective and bind well. Two refinements from the PP [5] have to be discussed here in the ST as the assurance level is increased. The refinement for ALC_CMS from the PP [5] can even be applied at the assurance level EAL 5 augmented with ALC_CMS.5. The assurance component ALC_CMS.4 is augmented to ALC_CMS.5 with aspects regarding the configuration control system for the TOE. The refinement is not touched. The refinement for ADV_FSP from the PP [5] can even be applied at the assurance level EAL 5 augmented with ADV_FSP.5. The assurance component ADV_FSP.4 is extended to ADV_FSP.5 with aspects regarding the description level. The level is increased from informal to semi-formal with informal description. The refinement is not touched by this measure. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 63 of 71 7 TOE SUMMARY SPECIFICATION This chapter 7 TOE Summary Specification contains the following sections: 7.1 List of Security Functional Requirements 7.1 List of Security Functional Requirements SFR1: FPT_FLS.1: Failure with preservation of secure state The detection thresholds of TOE’s detectors are inside the operating range of the TOE. Therefore abnormal events/failures are detected before the secure state is compromised. This allows to take User’s defined appropriate actions by software or to immediately RESET the TOE. TOE’s Detectors These functions records in register the events notified by the detectors (refer to list below). The software configures the reaction in case of detection:  The TOE is immediately reset when an event is detected.  Or, a special function register bit is set. List of detectors:  Abnormal frequency Detector  Abnormal voltage Detector  Abnormal temperature Detector  Light Detector  Active shield removal Detector  Glitch Detector  Life Cycle detector SFR2: FRU_FLT.2: Limited fault tolerance All operating signals (Clock, RESET and supply voltage) are filtered/regulated in order to prevent malfunction. TOE’s Filters These filters are used for preventing noise, glitches and extremely high frequency in the external reset or clock pad from causing undefined or unpredictable behavior of the chip.  High Frequency Filter  Reset Noise Filter TOE’s filters and detectors are implemented by the hardware. The filtering and detection cannot be affected or bypassed by Smartcard Embedded Software. The reaction to the detection can be configured by the software. The influence on security and the way how to configure it is described in details in the S3FV9QM/S3FV9QK User’s Manual. Therefore, FRU_FLT.2 is implemented by TOE. SFR3: FPT_PHP.3: Resistance to physical attacks CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 64 of 71 This requirement is achieved by security feature as the Active shield must be removed and bypassed in order to perform physical intrusive attacks. The TOE makes a reset or FIQ occurs to stops operation if a physical manipulation or physical probing attack is detected. So these functionalities meet the security functional requirement of FPT_PHP.3: Resistance to physical attack. SFR4: FDP_ACC.1: Subset access control This requirement is achieved by security register access control, invalid address access and access right for the code executed in FLASH. SFR5: FDP_ACF.1: Security attributes based access control. This is covered by the Privilege and User modes of the TOE. SFR6: FMT_MSA.3: Static attribute initialization. All Special Function Registers including MPU have DEFAULT values after Power on Reset. SFR7: FMT_MSA.1: Management of security attributes. This is achieved with the MPU feature. The Memory Protection Unit (MPU) enables user to partition memory and set individual protection attributes for each partition. SFR8: FMT_SMF.1: Specification of management functions. This is achieved via access to Special Function Registers of Memory Protection Unit(MPU). MPU provides Special Function Registers which defines the base address and the limit address for a partition. The Registers exist for Flash, and RAM. Additional Registers exist for defining the protection attribute for each partition. SFR9: FAU_SAS.1: Audit Storage This is fulfilled by the traceability/identification data written once and for all during the TEST mode of the manufacturing process. SFR10: FMT_LIM.1: Limited capabilities TEST mode can be accessed only by the TEST administrator by supplying an authentication password through a proprietary protocol. Once the TOE is changed to NORMAL mode, TEST mode functions are no more available for NORMAL mode. SFR11: FMT_LIM.2: Limited availabilities TEST mode can be accessed only by the TEST administrator by supplying an authentication password through a proprietary protocol. Once the TOE is changed to NORMAL mode, TEST mode commands are no more available for NORMAL mode. Functional test during manufacturing process is only available for TEST mode only. SFR12: FDP_IFC.1: Subset information flow control Memory Encryption: This is achieved by the function protects the memory contents of the TOE from data analysis on the stored data as well as on internally transmitted data. The algorithms used for encryption are proprietary. The ROM encryption is static key while the RAM and the CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 65 of 71 FLASH encryption is dynamic key. RAM encryption is performed automatically while FLASH encryption is defined and managed by the embedded software. SFR13: FDP_ITT.1: Basic internal transfer protection This requirement is achieved by the combination of the TOE security features as it is unpractical to get access to internal signals and interpret them. SFR14: FPT_ITT.1: Basic internal TSF data transfer protection This requirement is achieved by the combination of the TOE security features TOE features as it is unpractical to get access to internal signals and interpret them. SFR15: FCS_RNG.1: Random number generation This requirement is ensured by a True Random Number Generator ( DTRNG) that follow the requirement of the “standard” level of ANSSI requirements as well as BSI-AIS31 Class P2 requirements (German metric) for Random Number Generation(FCS_RNG.1). SFR16: FCS_COP.1: Cryptographic operation This requirement is covered by the TOE. Triple Data Encryption Standard Engine This function is used for encrypting and decrypting data using the Triple DES symmetric algorithm with 112bit or 168bit key size. (FCS_COP.1/3DES) TORNADO-E RSA Cryptographic Library as part of Secure RSA/ECC library (optional) This function assists in the acceleration of modulo exponentiations required in the RSA encryption/decryption algorithm. (FCS_COP.1/RSA) TORNADO-E is a high speed modular multiplication coprocessor for the support of the RSA public key cryptosystem. The TORNADO-E RSA Library is the software built on the TORNADO-E coprocessor that provides high level interface for RSA-based algorithms. The functions of the library included in the evaluation are:  TND_RSA_SigSTD_Secure (RSA signature generation with the standard method) This function performs the RSA signature generation with the standard method. It implements several countermeasures against the timing attack, the simple power analysis attack (SPA), the differential power analysis attack (DPA) and the fault injection attack.  TND_RSA_SigCRT_Secure (RSA signature generation with CRT method) This function performs the RSA signature generation with the Chinese-Remainder-Theorem (CRT) method. It implements several countermeasures against the timing attack, SPA, DPA and the fault injection attack.  TND_RSA_Verify (RSA signature verification) This function performs the RSA signature verification. Since this function uses only the public information, it does not implement any dedicated countermeasures against the side-channel attacks.  RSA_R2modM_precompute_sec (R^2 value precomputation for the standard RSA) This function calculates the R^2 value for the Montgomery constant R, which will then be used for the subsequent standard RSA operations.  RSA_R2modPandQ_precompute_sec (R^2 value precomputation for the CRT RSA) This function calculates the R^2 value for the Montgomery constant R, which will then be used for the subsequent CRT RSA operations. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 66 of 71 The TND_RSA_SigSTD_Secure and TND_RSA_SigCRT_Secure have some countermeasure against the timing attack, SPA, DPA and the fault attack. The RSA_R2modM_precompute_sec and RSA_R2modPandQ_precompute_sec functions implement some countermeasures against the fault attack. TORNADO-E ECC Cryptographic Library as part of Secure RSA/ECC library (optional) This function assists in the acceleration of required for the ECC cryptographic operations including the ECDSA signature generation/verification and the ECDH secret key derivation. (FCS_COP.1/ECDSA and FCS_COP.1/ECDH) TORNADO-E RSA/ECC library provides a set of functions to implement elliptic curve cryptographic algorithms. In particular, it provides some functions to implement the ECDSA signature generation/verification and the ECDH secret key derivation. The functions of the library included in the evaluation are:  ECDSA_sign_digest This function generates the ECDSA signature for the given message digest.  ECDSA_verify_digest This function verifies the given ECDSA (digested) message/signature pair.  ECDH_generate This function generates a shared secret value for the ECDH key exchange protocol. It implements several countermeasures against the timing attack, SPA, DPA and the fault attack. The TORNADO-E Secure RSA/ECC library provides the functions to calculate hash (digest) values using the SHA1, SHA224, SHA256, SHA384 and SHA 512 algorithm as specified in [FIPS PUB 180-3], but only the functions related to SHA224, SHA256, SHA384 and SHA512 listed below are in the scope of this evaluation:  SHA224_init, SHA224_update, SHA224_final,  SHA256_init, SHA256_update, SHA256_final.  SHA384_init, SHA384_update, SHA384_final.  SHA512_init, SHA512_update, SHA512_final. These functions are not security relevant functions, i.e. they must not be used to hash security values like keys etc. There are implemented no countermeasures against side channel attacks. The TOE provides the functionality of hash computation if and only if the optional TORNADO-E Secure RSA/ECC library is delivered. AES (Advanced Encryption Standard) This function supports the AES operation with 128 bit, 192bit and 256bit key size. (FCS_COP.1/AES) SFR17: FCS_CKM.1: Cryptographic key generation This requirement is covered by the TOE for the RSA/ECC key generation. (optional) RSA_KeyGen_Secure - FCS_CKM.1/RSA. This function generates an RSA public/private key pair. ECDSA_keygen - FCS_CKM.1/ECDSA. This function generates an ephemeral or static public/private key for the ECDSA signature generation. It implements several countermeasures against the timing attack, SPA and the fault CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 67 of 71 attack. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 68 of 71 8 ANNEX 8.1 Glossary Application Data All data managed by the Security IC Embedded Software in the application context. Application data comprise all data in the final Security IC. Composite Product Integrator Role installing or finalising the IC Embedded Software and the applications on platform transforming the TOE into the unpersonalised Composite Product after TOE delivery. The TOE Manufacturer may implement IC Embedded Software delivered by the Security IC Embedded Software Developer before TOE delivery (e.g. if the IC Embedded Software is implemented in ROM or is stored in the non-volatile memory as service provided by the IC Manufacturer or IC Packaging Manufacturer) Composite Product Manufacturer The Composite Product Manufacturer has the following roles (i) the Security IC Embedded Software Developer (Phase 1), (ii) the Composite Product Integrator (Phase 5) and (iii) the Personaliser (Phase 6). If the TOE is delivered after Phase 3 in form of wafers or sawn wafers (dice) he has the role of the IC Packaging Manufacturer (Phase 4) in addition. End-consumer User of the Composite Product in Phase 7. IC Dedicated Software IC proprietary software embedded in a Security IC (also known as IC firmware) and developed by the IC Developer. Such software is required for testing purpose (IC Dedicated Test Software) but may provide additional services to facilitate usage of the hardware and/or to provide additional services (IC Dedicated Support Software).. IC Dedicated Test Software That part of the IC Dedicated Software (refer to above) which is used to test the TOE before TOE Delivery but which does not provide any functionality thereafter. IC Dedicated Support Software hat part of the IC Dedicated Software (refer to above) which provides functions after TOE Delivery. The usage of parts of the IC Dedicated Software might be restricted to certain phases. Initialisation Data Initialisation Data defined by the TOE Manufacturer to identify the TOE and to keep track of the Security IC’s production and further life-cycle phases are considered as belonging to the TSF data. These data are for instance used for traceability and for TOE identification (identification data). CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 69 of 71 Integrated Circuit (IC) Electronic component(s) designed to perform processing and/or memory functions. Pre-personalisation Data Any data supplied by the Card Manufacturer that is injected into the non-volatile memory by the Integrated Circuits manufacturer (Phase 3). These data are for instance used for traceability and/or to secure shipment between phases. Security IC Composition of the TOE, the Security IC Embedded Software, User Data and the package (the Security IC carrier). Security IC Embedded Software Software embedded in a Security IC and normally not being developed by the IC Designer. The Security IC Embedded Software is designed in Phase 1 and embedded into the Security IC in Phase 3 or in later phases of the Security IC product life-cycle. Some part of that software may actually implement a Security IC application others may provide standard services. Nevertheless, this distinction doesn’t matter here so that the Security IC Embedded Software can be considered as being application dependent whereas the IC Dedicated Software is definitely not. Security IC Product Composite product which includes the Security Integrated Circuit (i.e. the TOE) and the Embedded Software and is evaluated as composite target of evaluation in the sense of the Supporting Document TOE Delivery The period when the TOE is delivered which is either (i) after Phase 3 (or before Phase 4) if the TOE is delivered in form of wafers or sawn wafers (dice) or (ii) after Phase 4 (or before Phase 5) if the TOE is delivered in form of packaged products. TOE Manufacturer The TOE Manufacturer must ensure that all requirements for the TOE and its development and production environment are fulfilled. The TOE Manufacturer has the following roles: (i) IC Developer (Phase 2) and (ii) IC Manufacturer (Phase 3). If the TOE is delivered after Phase 4 in form of packaged products, he has the role of the (iii) IC Packaging Manufacturer (Phase 4) in addition. TSF data Data created by and for the TOE, that might affect the operation of the TOE. This includes information about the TOE’s configuration, if any is coded in non-volatile non-programmable memories (ROM), in specific circuitry, in non-volatile programmable memories (for instance E2PROM) or a combination thereof. User data All data managed by the Smartcard Embedded Software in the application context. User data comprise all data in the final Smartcard IC except the TSF data. CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 70 of 71 8.2 Abbreviations CC Common Criteria EAL Evaluation Assurance Level IT Information Technology PP Protection Profile ST Security Target TOE Target of Evaluation TSC TSF Scope of Control TSF TOE Security Functionality TSFI TSF Interface TSP TOE Security Policy CAYUSE SECURITY TARGET LITE PUBLIC Version 3.0 Page 71 of 71 8.3 Literature [1] Common Criteria, Part 1: Common Criteria for Information Technology Security Evaluation, Part 1: Introduction and General Model, Version 3.1, Revision 3, July 2009, CCMB-2009-07-001 [2] Common Criteria, Part 2: Common Criteria for Information Technology Security Evaluation, Part 2: Security Functional Components, Version 3.1, Revision 3, July 2009, CCMB-2009-07-002 [3] Common Criteria, Part 3: Common Criteria for Information Technology Security Evaluation, Part 3: Security Assurance Components, Version 3.1, Revision 3, July 2009, CCMB-2009-07-003 [4] Common Methodology for Information Technology Security Evaluation, Evaluation Methodology, Version 3.1, Revision 3, July 2009, CCMB-2009-07-004 [5] Eurosmart Security IC Platform Protection Profile, Version 1.0, June 2007, BSI-PP-0035. [6] AIS31: Functionality classes and evaluation methodology for true (physical) random number generators, Version 1, 25.09.2001, Bundesamt für Sicherheit in der Informationstechnik [7] AIS20: Functionality classes and evaluation methodology for deterministic random number generators, Version 1, 2.12.1999, Bundesamt für Sicherheit in der Informationstechnik [8] ALGO: Federal Gazette No 19, Notification in accordance with the Electronic Signatures Act and the Electronic Signatures Ordinance (overview of suitable algorithms), Federal Network Agency for Electricity, Gas, Telecommunications, Post and Railway, 2008-11-17 [10] [FIPS SP800-67] Recommendation for the Triple Data Encryption Algorithm (TDEA) Block Cipher, version 1.1 [11] [FIPS 197] Advanced Encryption Standard (AES), 2001-11-26 [12] [ISO/IEC 14888-2:2008] - Information technology -- Security techniques-- Digital signatures with appendix -- Part 2: Integer factorization based mechanisms. [13] CC Supporting Document, Mandatory Technical Document, Application of Attack Potential to Smartcards, Version 2.5, Revision 1, April 2008, CCDB-2008-04-001 [14] [ANS X9.62] American National Standard X9.62-2005, Public Key Cryptography for the Financial Services Industry, The Elliptic Curve Digital Signature Algorithm (ECDSA), November 16, 2005. [15] [ANS X9.63] American National Standard X9.63-2001, Public Key Cryptography for the Financial Services Industry: Key Agreement and Key Transport Using Elliptic Curve Cryptography, November 20, 2001 [16] [FIPS PUB 180-3] U.S. Department of Commerce / National Bureau of Standards, Secure Hash Algorithm, FIPS PUB 180-3, 2008-October [17] [Brainpool curves] ECC Brainpool Standard Curves and Curve generation, M. Lochter, v1.0, www.ecc- brainpool.org [18] [NIST curves] Federal Information Processing Standards Publication FIPS PUB 180-3, Digital Signature Standard; U.S. department of Commerce / National Institute of Standards and Technology (NIST), June 2009 [19] [SEC-recommended curves] SEC2: Recommended Elliptic Curve Domain Parameters, Certicom Research, v1.0, September 20, 2000. [20] [ETSI TS 102 176-1] Electronic Signatures and Infrastructures (ESI); Algorithms and Parameters for Secure Electronic Signatures; Part 1: Hash functions and asymmetric algorithms, 2007-11, version 2.0.0 [21] [SCA on Prime Gen] T. Finke, M. Gebhardt and W. Schindler, A New Side-Channel Attack on RSA Prime Generation, CHES 2009, LNCS 5747, pp. 141-155, 2009.