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MultiApp ID IAS ECC
Security Target
UPDATES
Date Author Modifications
Jan 06, 2010 Christine Crippa-Martinez Creating from evaluated ST (V1.9)
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No disclosure to a third party without prior written consent of Gemalto
CONTENT
1 ST INTRODUCTION..................................................................................................................................................5
1.1 ST REFERENCE .......................................................................................................................................................5
1.2 TOE REFERENCE ....................................................................................................................................................5
1.3 TOE OVERVIEW......................................................................................................................................................6
1.3.1 TOE type........................................................................................................................................................7
1.3.2 TOE boundaries and out of TOE ...................................................................................................................7
1.4 TOE DESCRIPTION ..................................................................................................................................................8
1.4.1 Platform description ......................................................................................................................................8
1.4.2 IAS ECC Applet description...........................................................................................................................9
1.4.3 TOE life-cycle ..............................................................................................................................................11
1.4.3.1 TOE Phases................................................................................................................................................................13
1.4.4 TOE Environment ........................................................................................................................................13
1.4.4.1 Development phase....................................................................................................................................................14
1.4.4.2 Production environment ............................................................................................................................................15
1.4.4.3 Personalization environment......................................................................................................................................15
1.4.4.4 User environment.......................................................................................................................................................15
1.4.5 The actors and roles ....................................................................................................................................16
1.4.6 TOE intended usage.....................................................................................................................................17
1.5 REFERENCES, GLOSSARY AND ABBREVIATIONS ...................................................................................................19
1.5.1 External references......................................................................................................................................19
1.5.2 Glossary.......................................................................................................................................................20
1.5.3 Abbreviations...............................................................................................................................................21
2 CONFORMANCE CLAIMS....................................................................................................................................23
2.1 CC CONFORMANCE CLAIM....................................................................................................................................23
2.2 PP CLAIM, PACKAGE CLAIM..................................................................................................................................23
2.3 CONFORMANCE RATIONALE..................................................................................................................................23
2.4 PP REFINEMENTS ..................................................................................................................................................23
2.5 PP ADDITIONS.......................................................................................................................................................27
2.6 ASSURANCE REQUIREMENTS ADDITIONAL TO THE PP ...........................................................................................27
2.7 PP CLAIMS RATIONALE .........................................................................................................................................27
3 SECURITY PROBLEM DEFINITION...................................................................................................................28
3.1 DIGITAL SIGNATURE ASSETS.................................................................................................................................28
3.2 DIGITAL SIGNATURE SUBJECTS..............................................................................................................................28
3.3 DIGITAL SIGNATURE THREATS ..............................................................................................................................29
3.4 DIGITAL SIGNATURE ASSUMPTIONS ......................................................................................................................29
3.5 ORGANIZATIONAL SECURITY POLICIES ..................................................................................................................30
4 SECURITY OBJECTIVES.......................................................................................................................................30
4.1 SECURITY OBJECTIVES FOR THE TOE ...................................................................................................................31
4.2 SECURITY OBJECTIVES FOR THE OPERATIONAL ENVIRONMENT .............................................................................32
4.3 SECURITY OBJECTIVES RATIONALE .......................................................................................................................33
4.3.1 Threats .........................................................................................................................................................33
4.3.2 Assumptions .................................................................................................................................................35
4.3.2.1 Additional..................................................................................................................................................................35
4.3.3 Organisational security policies..................................................................................................................35
5 EXTENDED COMPONENTS DEFINITION.........................................................................................................35
6 SECURITY REQUIREMENTS ...............................................................................................................................37
6.1 TOE SECURITY FUNCTIONAL REQUIREMENTS .......................................................................................................37
6.1.1 Security functional requirements list ...........................................................................................................37
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6.1.2 FCS – Cryptographic support......................................................................................................................38
6.1.2.1 FCS_CKM cryptographic key management ..............................................................................................................38
6.1.2.2 FCS_COP Cryptographic operation ..........................................................................................................................39
6.1.3 FDP: User data protection..........................................................................................................................40
6.1.3.1 FDP_ACC Access Control policy..............................................................................................................................40
6.1.3.2 FDP_ACF access control function.............................................................................................................................41
6.1.3.3 FDP_ETC :Export to outside TSF control.................................................................................................................43
6.1.3.4 FDP_ITC Import From outside TSF control..............................................................................................................43
6.1.3.5 FDP_RIP Residual information protection................................................................................................................44
6.1.3.6 FDP_SDI Stored data integrity..................................................................................................................................44
6.1.3.7 FDP_UCT Inter-TSF user data confidentiality transfer protection............................................................................45
6.1.3.8 FDP_UIT Inter-TSF user data integrity transfer protection......................................................................................45
6.1.4 FIA: Identification and authentication ........................................................................................................46
6.1.4.1 FIA_AFL Authentication failure ...............................................................................................................................46
6.1.4.2 FIA_ATD User attribute definition............................................................................................................................46
6.1.4.3 FIA_UAU User authentication ..................................................................................................................................46
6.1.4.4 FIA_UID User Identification....................................................................................................................................47
6.1.5 FMT: Security management.........................................................................................................................47
6.1.5.1 FMT_MOF Management of functions in TSF...........................................................................................................47
6.1.5.2 FMT_MSA Management of security attributes .........................................................................................................47
6.1.5.3 FMT_MTD Management of TSF data.......................................................................................................................48
6.1.5.4 FMT_SMF Specification of Management Functions.................................................................................................48
6.1.5.5 FMT_SMR Security management roles.....................................................................................................................48
6.1.6 FPT: Protection of the TSF .........................................................................................................................49
6.1.6.1 FPT_EMSEC TOE Emanation ..................................................................................................................................49
6.1.6.2 FPT_FLS Failure secure............................................................................................................................................49
6.1.6.3 FPT_PHP TSF physical Protection ...........................................................................................................................49
6.1.6.4 FPT_TST TSF self test ..............................................................................................................................................50
6.1.7 FTP: Trusted Path / Channel.......................................................................................................................50
6.1.7.1 FTP_ITC Inter-TSF trusted channel..........................................................................................................................50
6.1.7.2 FTP_TRP Trusted path..............................................................................................................................................51
6.2 SECURITY ASSURANCE REQUIREMENTS ................................................................................................................53
6.2.1 TOE security assurance requirements list ...................................................................................................53
7 TOE SUMMARY SPECIFICATION.....................................................................................................................56
7.1 TOE SECURITY FUNCTIONALITIES PROVIDED BY PLATFORM ................................................................................56
7.1.1 TSF_CARD_EMANATION: Emanation protection.....................................................................................56
7.1.2 TSF_CARD_PROTECT: Card operation protection...................................................................................56
7.2 TOE SECURITY FUNCTIONALITIES PROVIDED BY IAS ECC APPLET .........................................................................56
7.2.1 TSF_ AUTHENTICATION: Authentication management............................................................................56
7.2.2 TSF_CRYPTO: Cryptography management................................................................................................57
7.2.3 TSF_INTEGRITY: Integrity monitoring ......................................................................................................57
7.2.4 TSF_MANAGEMENT: operation management and access control............................................................58
7.2.5 TSF_SECURE_MESSAGING: secure messaging management ..................................................................58
FIGURES
Figure 1 - Multiapp ID IAS ECC Card.......................................................................................................................................................7
Figure 2 - MultiApp platform architecture .................................................................................................................................................9
Figure 3 - Type 2 and Type 3 SSCD operations.......................................................................................................................................10
Figure 4 - Product Life Cycle “module delivery”.....................................................................................................................................12
Figure 5 - TOE Usage...............................................................................................................................................................................18
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TABLES
Table 1. TOE component ...........................................................................................................................................................................5
Table 2. Multiapp ID IAS ECC Card components ....................................................................................................................................6
Table 3. Smart Card Product Life Cycle...................................................................................................................................................13
Table 4. PP functional requirements that have been refined....................................................................................................................24
Table 5. IAS Classic security functional requirements list......................................................................................................................38
Table 6. SAR CC V2.3 versus CC V3.1...................................................................................................................................................54
Table 7. TOE security assurance requirements list..................................................................................................................................55
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1 ST INTRODUCTION
1.1 ST REFERENCE
ST Title: IAS-ECC - Security Target
ST Reference: D1111555-Pub
Origin: GEMALTO
ITSEF Serma
Certification scheme: French (DCSSI)
This ST has been built with:
Common Criteria for Information Technology Security Evaluation Version 3.1 which comprises [CCPART1],
[CCPART2], and [CCPART3]
Table 1 gives an overview of the components of the TOE.
Component Version number Supplier
Hardmask in ROM 1.0 Gemalto
Softmask 1.2 Gemalto
Applet IAS ECC 4.2.7.A Gemalto
Micro-controller P5CD144 V0B NXP
Table 1. TOE component
1.2 TOE REFERENCE
TOE Title: IAS ECC
Product name: Multiapp ID IAS ECC
Commercial name: MultiApp ID IAS ECC
Product reference: T1009875
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1.3 TOE OVERVIEW
The Target of Evaluation (TOE) is composed of the Multiapp platform and the electronic signature application
IAS ECC. The platform includes the hardware and the operating system.
The product is a Smart Card Integrated Circuit (IC) with the Multiapp platform, the IAS ECC applet and the
(out-of-TOE) applications defined in Table 2. All ROMed applets are deactivated; IAS ECC application is
installed in EEPROM.
TOE Components Version Constructor
Micro Controller (P5CD144) V0B NXP
Embedded software (platform) Multiapp version 1.0 GEMALTO
Digital signature application (Applet)
in (E2PROM)
IAS ECC GEMALTO
Other non TOE Components Version Constructor
Instantiable ROMed applet N/A
Not instantiable ROMed applets
(entry point deactivated)
Table 2. Multiapp ID IAS ECC Card components
The TOE defined in this Security Target is the Secure Signature Creation Device (SSCD) functionalities
provided by the IAS ECC application, and supported by the Multiapp Java Card platform.
The other applications are locked and cannot be instantiated or personalized. They are not in the TOE scope
and therefore not part of the evaluation.
The TOE will be designed and produced in a secure environment and used by each citizen in a hostile
environment.
The product provides an electronic signature services:
• Signature creation
• Signature verification
• Key importation
• Key generation (on board)
The Gemalto IAS ECC application is compliant with E-sign specifications (PK and SK authentication).
It covers the identity, digital signature and data storage services. The Digital signature key size is 1024, 1536 or
2048 bits.
The other applications are not in the TOE Scope of Control and therefore not part of the evaluation.
The TOE is a Secure Signature Creation Device (SSCD) that provides both SCD/SVD generation and
Signature creation as described in the Protection Profile [PP SSCD2] and Protection Profile [PP SSCD3].
The electronic signature security functions take advantage of the platform security functions:
• Hardware Tamper Resistance is managed by the chip security layer that meets PP SSVG [PP/BSI-
0002].
• Secure operation of the Multiapp platform managed inside platform component.
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1.3.1 TOE type
The product is a smartcard including a plastic card and a module performing the interface between reader and
the embedded chip. Other smart card product elements (such as holograms, security printing…) are outside
the scope of this Security Target. The Target of Evaluation (TOE) is the Smart Card Integrated Circuit with
Embedded Software in operation and in accordance to its functional specifications.
1.3.2 TOE boundaries and out of TOE
The TOE is composed of the IC, the software platform and a digital signature application:
• P5CD144 IC which has been certified separately according to [IC-ST] claiming [PP/BSI-0002]
• Multiapp platform
• IAS ECC application
The TSFs are composed of:
1. The digital-signature related functions of the IAS ECC application: Signatory Authentication, Signature
Creation, SCD/SVD Generation, SCD Import & storage, SVD Export, RAD Import & storage. (Other
functions are out of the TOE)
2. Part of Multiapp platform that installs and supports the IAS ECC application. (Other multiapp platform
function are out of the TOE)
3. The P5CD144 IC to supports the Multiapp platform.
Beside the TOE, the product also contains the following Java Card applications (out of scope of the TOE)
Figure 1 represents the product. The TOE is bordered with bold and un-continuous line. The architecture of
Multiapp inside the TOE is presented in platform description chapter below.
Remark: ROMed applications are deactivated (entry point deactivated).
Figure 1 - Multiapp ID IAS ECC Card
IAS
ECC
Integrated circuit P5CD144 + Crypto libraries
Multiapp
Javacard platform JC 2.2.1 GP 2.1.1
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1.4 TOE DESCRIPTION
1.4.1 Platform description
MultiApp is a Java Open Platform that complies with two major industry standards:
1. Sun’s Java Card 2.2.1, which consists of the Java Card 2.2.1 Virtual Machine, Java Card 2.2.1 Runtime
Environment and the Java Card 2.2.1 Application Programming Interface.
2. The GlobalPlatform Card Specification version 2.1.1
MultiApp contains the following components (see Figure 2):
• The Native Layer that provides the basic card functionalities (memory management, I/O management
and cryptographic libraries) with native interface with the dedicated IC. The cryptographic library includes
TDES, RSA CRT (1024, 1536, 2048), hashing (SHA-1, SHA-256), OBKG (RSA), and RNG.
• The Java Card Runtime Environment, which provides a secure framework for the execution of Java
Card programs and data access management (firewall).
• The Java Card Virtual Machine, which provides the secure interpretation of bytecodes.
• The API including the standard Java Card API, the JCF API (Biometry) and Gemalto proprietary API
(SecureAPI, GemUtil, Mifare, CryptoTest).
• The Open Platform Card Manager, which provides card, key and application management functions
(contents and life-cycle) and security control.
The MultiApp platform provides the following services:
Remark: Points 2, 3 and 4 are services available in development environment phase and no available in
operational environment (not part of the evaluation scope).
1. Initialization of the Card Manager and management of the card life cycle,
2. Secure installation of the application under Card Manager control,
3. Extradition services to allow several applications to share a dedicated security domain,
4. Deletion of applications under Card Manager control,
5. Secure operation of the applications through the API,
6. Card basic security services as follows:
− Checking environmental operating conditions using information provided by the IC,
− Checking life cycle consistency,
− Ensuring the security of the PIN objects,
− Generating random number,
− Handling secure data object and backup mechanisms,
− Managing memory content,
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Figure 2 - MultiApp platform architecture
1.4.2 IAS ECC Applet description
IAS ECC is a Java Card application that provides a Digital Signature Creation Device [SSCD] as defined in the
DIRECTIVE 1999/93/EC of the European Parliament and of the Council of 13 December 1999 on a
Community Framework for electronic signatures.
Three Protection Profiles have been defined:
• The SSCD PP Type 1, which is a SCD/SVD generation component without signature creation and
verification. The SCD generated on a SSCD Type 1 shall be exported to a SSCD Type 2 over a trusted
channel [PP SSCD1].
• The SSCD PP for a TOE Type 2, which is a Signature creation and verification component [PP SSCD2].
This device imports the SCD from a SSCD Type 1
• The SSCD PP for a TOE Type 3, which is combination of the TOE Type 1 and Type 2 – i.e. Generation
and Signature creation/verification component [PP SSCD3].
Terminology
In this document the terminology of [PP SSCD2] and [PP SSCD3] is used.
The SSCD Application uses public key encryption. The Signature Creation Data (SCD) is the private key and
the Signature Verification Data (SVD) is the public key.
The Signatory's Reference Authentication Data (RAD) is the PIN stored in the card and the Signatory's
Verification Authentication Data (VAD) is the PIN provided by the user.
SSCD Application provides the following functions necessary for devices involved in digital electronic
signatures:
1. Generate the (SCD) and the correspondent (SVD), or Load the SCD,
2. Create qualified electronic signatures:
IC P5CD144
Native Layer
Memory Manager Communication (I/O) Crypto Libs
Virtual Machine
JC 2.2.1 Key Objects
API
JC2.2.1/JCF/Gemalto
Propriatery
Card Manager,
OP/GP API
OP 2.1.1
Runtime Environment
JC 2.2.1
JC/GP support
JC/GP support
Application
Layer Electronic signature
Applet
EEPROM
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(a) After allowing for the Data To Be Signed (DTBS) to be displayed correctly by an appropriate
environment,
(b) Using appropriate hash functions agreed according to [CWA-ALGO] suitable for qualified electronic
signatures,
(c) After appropriate authentication of the signatory by the TOE itself,
(d) Using appropriate cryptographic signature function that employs appropriate cryptographic
parameters agreed according to [CWA-ALGO].
The TOE implements all IT security functionalities, which are necessary to ensure the secrecy of the SCD. To
prevent the unauthorized usage of the SSCD the TOE provides user authentication and access control. The
TOE implements IT measures to support a trusted path to a trusted human interface device. Therefore, the
TOE holds Signatory's Reference Authentication Data (RAD) that is used to verify the verification data provided
by the user as Signatory's Verification Authentication Data (VAD).
The TOE is initialized by importing an SCD or by generating a pair of SCD and SVD. The SCD is protected so
as to be solely used in the signature-creation process by the legitimate signatory during the validity of this
SCD/SVD pair.
The TOE stores the SCD and may export the SVD. The SVD corresponding to the signatory’s SCD will be
included in the certificate of the signatory by the certificate-service-provider (CSP).
When in usage phase, the TOE allows the creation of a new SCD/SVD pair. The previous SCD shall be
destroyed before the creation of the new SCD/SVD pair.
The signatory uses a signature-creation system to create electronic signatures. The signature-creation device
consists of the TOE.
The SCA presents the DTBS to the signatory and prepares the DTBS-representation that the signatory wishes
to sign for performing the cryptographic function of the signature.
The TOE returns the digital electronic signature.
The TOE implements the SSCD of type 2 and type 3, and all functions concerning the SSCD to create
electronic signatures in a secure way.
The Figure below shows the type 3 and type 2 TOE operations as defined in [PP SSCD2] & [PP SSCD3].
SVD Export
SCD/SVD Generation
Signature Creation
User
Authentication
Personalization
SCD Import
SSCD Type 2 & 3
Trusted
Path
Trusted
channel
Trusted
Channel
Trusted
Channel
SCA
DTBS representation
SDO
CGA
Init/SVD into
certificate
Other SSCD Type 1
HI
Authentication data
Figure 3 - Type 2 and Type 3 SSCD operations
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1.4.3 TOE life-cycle
The product life cycle is described in Figure 4 - Product Life Cycle. Some remarks are added to explain this
figure regarding Table 3. Smart Card Product Life Cycle.
• The TOE is the product at the end of the phase 5 “Smart card product finishing process”.
• Platform design and application design correspond to the phase 1 “Smart card software
development”.
• Hardware design corresponds to the phase 2 “IC development”.
• Hardware fabrication corresponds to the phase 3” IC manufacturing and testing”
• IC packaging and testing corresponds to the phase 4.
• Application installation is done in the phase 5.
• Loading of softmask is done in the phase 5.
• Loading of application data, SCD/SVD import (type 2), and SVD export (for certificate) are done
in the phase 6 “Smart card personalization”.
• SCD/SVD generation (type 3) and signature creation correspond to the phase 7“Smart card end-
usage”.
• SSCD destruction corresponds to the end of the phase 7.
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Phase 7
Phase 6
Phase 3
IC manufacturing
and testing
Phase 4
IC packaging and testing
Module assembling & packaging
Smart card personalization
Product end-usage
Phase 1
Platform
design
Application
design
Softmask design
& IAS ECC
Phase 5
Smart cards pre-personalization Softmask & IAS
ECC loading
Phase 2
HW design
HW dedicated software
HW fabrication, OS and
application implementation
SVD export
SCD/SVD import
Signature Creation
SSCD destruction
SCD/SVD generation
TOE delivery
Dev.
Environment
Prod.
Environment
TOE
Dev.
Phase
Perso.
Env
User.
Env
TOE
Oper.
Phase
Figure 4 - Product Life Cycle “module delivery”
The global security requirements of the TOE mandate to consider, during the development phase, the threats
to security occurring in the other phases.
Therefore, this ST addresses the functions used in the phases 6 and 7 but developed during the phases 1 to 5.
The limits of the evaluation process correspond to phases 1 to 5 including the TOE under development delivery
from the party responsible of each phase to the parties responsible of the following phases.
These different phases may be performed at different sites. This implies that procedures on the delivery
process of the TOE must exist and be applied for every delivery within a phase or between phases. This
includes any kind of delivery performed from phase 1 to 5 to subsequent phases, including:
• Intermediate delivery of the TOE or the TOE under construction within a phase,
• Delivery of the TOE or the TOE under construction from one phase to the next.
These procedures must be compliant with the security assurance requirements developed in TOE “Security
Assurance Requirements”.
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1.4.3.1 TOE Phases
1.4.3.1.1 TOE Actors & roles
For the digital signature application, two roles have been identified, the Administrator and the Signatory.
1. The Administrator acts during the personalization phase (phase 6). He creates the Signatory’s PIN
and optionally imports the first SCD into the TOE.
2. The Signatory that owns the TOE is the End-User in the usage phase (phase 7). He can sign, destroy
the SCD and generate a new SCD/SVD pair.
At the first usage of the TOE, the Signatory must change his PIN code before he is allowed to sign.
A new PIN is also required each time a new SCD/SVD pair is generated.
1.4.3.1.2 Smart Card product life cycle
The Smart card product life cycle, as defined in [PP/BSI-0002], is split up into 7 phases where the following
authorities are involved:
Phase 1 Smart card software
development
The smart card embedded software developer is in
charge of the smart card embedded software
development and the specification of IC pre-
personalization requirements.
Phase 2 IC Development The IC designer designs the integrated circuit,
develops IC firmware if applicable, provides information,
software or tools to the smart card software developer,
and receives the software from the developer, through
trusted delivery and verification procedures. From
the IC design, IC firmware and smart card embedded
software, he constructs the smart card IC database,
necessary for the IC photo mask fabrication.
Phase 3 IC manufacturing and
testing
The IC manufacturer is responsible for producing the
IC through three main steps: IC manufacturing, testing,
and IC pre-personalization.
Phase 4 IC packaging and
testing
The IC packaging manufacturer is responsible for the
IC packaging and testing.
Phase 5 Smart card product
finishing process
The smart card product manufacturer is responsible
for the smart card product finishing process and testing,
and the smart card pre-personalization
Phase 6 Smart card
personalization
The Personalizer is responsible for the smart card
personalization and final tests.
Administrator
Phase 7 Smart card end-usage The smart card issuer is responsible for the smart
card product delivery to the smart card end-user, and
for the end of life process.
Signatory
Administrator
Table 3. Smart Card Product Life Cycle
1.4.4 TOE Environment
The TOE environment is defined as follow:
• For TOE development phase:
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o Development environment corresponding to the software developer environment (phase1),
and the hardware fabrication environment (phase 2);
o Production environment corresponding to the generation of the masked Integrated Circuit
(phase 3), the manufacturing (phase 4), the initialization of the JavaCard (phase 5) and the
installation of the applet (phase 5), the test operations, and initialization of the JavaCard.
• For TOE operational phase
o Personalization environment corresponding to personalization and testing the loading of
TOE application data and the import of the SCD (phase 6), during which the card generates
the signatures on behalf of the end user.
o User environment corresponding to card usage (phase 7). End of life environment, during
which the TOE is made inapt for the signature creation (end of the phase 7).
Phase 1 Software development (Multiapp,
IAS ECC, softmask)
Pre-personalization design
Gemalto Meudon
Phase 2 IC design
Hardware fabrication
NXP
Phase 3 IC manufacturing & testing NXP
Phase 4 IC packaging & testing
Module assembling
Module packaging
Gemalto
Phase 5 Pre-personalization Gemalto
1.4.4.1 Development phase
1.4.4.1.1 Software development ((Phase 1)
This environment is limited to GEMALTO Meudon site.
In order to ensure security, the environment in which the development takes place must be made secure with
access control tracing entries. Furthermore, it is important that all authorized personnel feels involved and fully
understands the importance and the rigid implementation of the defined security procedures.
The development begins with the TOE specification. All parties in contact with sensitive information are
required to abide by Non-disclosure Agreement.
Design and development of the ES then follows. The engineers use a secure computer system (preventing
unauthorized access) to make the conception, design, implementation and test performances.
To ensure security, access to development tools and products elements (PC, emulator, card reader,
documentation, source code, etc…) is protected. The protection is based on measures for prevention and
detection of unauthorized access. Two levels of protection are applied:
• Access control to GEMALTO Meudon office and sensitive areas.
• Access to development data through the use of a secure computer system to design, implement and test
software.
Storage of sensitive documents, databases on tapes, diskettes, and printed circuit layout information are in
appropriately locked cupboards/safe. Of paramount importance also is the disposal of unwanted data
(complete electronic erasures) and documents (e.g. shredding).
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Testing, programming and deliveries of the TOE then take place. When these are done offsite, they must be
transported and worked on in a secure environment with accountability and traceability of all (good and bad)
products.
During the electronic transfer of sensitive data, procedures must be established to ensure that the data arrive,
only at the destination and is not accessible at intermediate stages (e.g. stored on a buffer server where
system administrators make backup copies). It must also be ensured that transfer is done without modification
or alteration.
1.4.4.1.2 Hardware fabrication (Phase 2)
This environment is limited to NXP sites.
The IC development environment is described in [IC-ST]. A transport key protects the IC delivery from Gemalto
to NXP. We are only interested below in the software aspect of the TOE.
1.4.4.2 Production environment
1.4.4.2.1 IC manufacturing (Phase 3)
This environment is limited to NXP sites.
The IC manufacturing environment is described in [IC-ST].
1.4.4.2.2 IC Packaging (phase 4)
This environment is limited to GEMALTO site,
Access to IC packaging and testing is physically protected. The protection is based on measures for prevention
and detection of unauthorized access.
During fabrication, phases 3, and 4, all the persons involved in storage and transportation operations should
fully understand the importance of the defined security procedures.
Moreover, the environment in which these operations take place must be secured.
1.4.4.2.3 Pre-personalization: Card Initialization and applet installation (phase 5)
This environment is limited to GEMALTO site,
Initialization requires a secure environment, which guarantees the integrity and confidentiality of operations.
Access to production is physically protected. The protection is based on measures for prevention and detection
of unauthorized access.
During smart card pre-personalization the application is loaded. Data structure for common element is created.
At the end of this phase, the ROMed applets entry points are deactivated.
1.4.4.3 Personalization environment
This environment can be GEMALTO site,
Recommendation is that, access to personalization site is physically protected. The protection is based on
measures for prevention and detection of unauthorized access.
Additional data may be loaded and the SCD may be imported. Then the TOE is issued to the Card Holder
(Signatory).
1.4.4.4 User environment
At the end of phase 6, the Card Issuer delivers the Smart Card to the Card Holder.
Once delivered to the Card Holder (phase 7), the TOE can generate the SCD/SVD key pair. The TOE then
exports the public part of the key to the Certification Authority for certification.
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The TOE is owned by the Card Holder who cannot impose strict security rules. It is the responsibility of the
TOE and of the signature protocols to ensure that the signature security requirements are met.
The signatory will generate the SCD/SVD keys pair.
The signatory will export the public key (SVD)
The signatory will have to present his PIN (VAD) before being allowed to create signature.
The end of life environment is corresponding to the physical destruction of the card.
1.4.5 The actors and roles
The actors can be divided in:
Developers
The IC designer and Dedicated Software (DS) developer designs the chip and its DS. For this TOE, it is NXP.
The Embedded Software developer designs the OS according to IC/DS specifications, the IAS ECC application
and the softmask. For this TOE, it is GEMALTO.
Manufacturers
The IC manufacturer -or founder- designs the photomask, manufactures the IC with its DS and hardmask from
the Product Developer. For this TOE, the founder is NXP.
The IC die bonding manufacturer is responsible for the die bonding the ICs provided by the founder. For this
TOE, the IC die bonding manufacturer is GEMALTO.
The Smart Card product manufacturer (or Card manufacturer) is responsible to obtain a pre-personalized card
from a packaged IC. In the phase 5, the card manufacturer is also responsible for loading additional code
belonging to the Developer and Manufacturer of the Card (the softmask). For this TOE, the Smart Card
product manufacturer is GEMALTO.
Personalizer
The Smart Card Personalizer personalizes the card by loading the cardholder data as well as cryptographic
keys and PINs. For this TOE, the personalizer is the Card Issuer.
At the end of this phase, no more applets may be loaded on the card (post-issuance is not allowed). The card
is issued in OP_SECURED state.
Card Issuer, Administrator
The Card Issuer -short named “issuer”- is a National Administration. It issues cards to the citizens who are the
“Card holders”. The Card Issuer has also the role of Administrator. Therefore, the Card Issuer is responsible
for selecting and managing the personalization, for managing applets, for creating the Signatory’s PIN, for
optionally importing the first SCD into the TOE, as well as for distribution and invalidation of the card.
End-user, Signatory
The Signatory is the End-user in the usage phase (phase 7) and owns the TOE. The card is personalized with
his or her identification and secrets. The Signatory can sign, destroy the SCD and generate a new SCD/SVD
pair.
The roles (administration and usage) are defined in the following tables.
Phase Administrator Environment
6 and 7 Card Issuer Personalization and Usage Environment
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Phase User Environment
7 Signatory Usage Environment
During the delivery between phases the responsibility is transferred from the current phase administrator to the
next phase administrator.
1.4.6 TOE intended usage
SCD import:
1. The SCA authenticates itself to the TOE.
2. The signatory authenticates to the TOE (see above).
3. The signatory requests the import of SCD from a SSCD Type 1 device.
4. The SCD is imported to the TOE.
5. The CGA generates the certificate for the corresponding SVD and sends it ot the TOE.
SCD/SVD Key generation in the final usage phase,
1. The SCA authenticates itself to the TOE.
2. The signatory enters his PIN code.
3. The signatory requests the generation of a SCD / SVD key pair
4. The SCD / SVD are generated in the TOE.
5. The SVD is sent to the CGA.
6. The CGA generates the certificate and sends it to the TOE.
Signature Creation in the final usage phase,
1. The SCA authenticates itself to the TOE.
2. The signatory enters his PIN code.
3. The signatory sends the DTBS to the TOE.
4. The TOE computes the Signature.
5. The TOE sends the Signature to the SCA.
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Signature
Creation
Application
(SCA)
Signatory
Authentication
SCD / SVD
Generation
Connected
Device
Smart Card
Human
Interface
DTBS / Signature
SVD / Certificate
Certification
Authority
(CA)
Certification
Generation
Application
(CGA)
Authentication Data
Signature - Creation
SVD / Certificate
Figure 5 - TOE Usage
SCD Import
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No disclosure to a third party without prior written consent of Gemalto
1.5 REFERENCES, GLOSSARY AND ABBREVIATIONS
1.5.1 External references
Reference Title - Reference
[CCPART1] Common Criteria for Information Technology Security
Evaluation Part 1: Introduction and general model CCMB-2006-09-001, version 3.1,
September 2006 (conform to ISO 15408).
[CCPART2] Common Criteria for Information Technology Security
Evaluation Part 2: Security Functional components CCMB-2007-09-002, version 3.1,
September 2007 (conform to ISO 15408).
[CCPART3] Common Criteria for Information Technology security
Evaluation Part 3: Security Assurance Requirements CCMB-2007-09-003, version 3.1,
September 2007 (conform to ISO 5408).
[CEM] Common Methodology for Information Technology Security
Evaluation CCMB-2007-09-004, version 3.1, September 2007.
[PP SSCD1] Protection Profile Creation Device Type 1 Version 1.05
BSI-PP-0004-2002T- 03-04-2002
[PP SSCD2] Protection Profile Creation Device Type 2 Version 1.04
BSI-PP-0005-2002T-03-04-2002
[PP SSCD3] Protection Profile Creation Device Type 3 Version 1.05
BSI-PP-0006-2002T-03-04-2002
[PP/BSI-0002] Smartcard IC Platform Protection Profile - BSI-PP-0002-2001; Version 1.0, July 2001
[DIRECTIVE] DIRECTIVE 1999/93/EC of the European Parliament and of the Council of 13 December
1999 on a Community Framework for electronic signatures”
DIRECTIVE 1999/93/EC
[E-Sign 1] Application Interface for Smart Cards used as Secure Signature Creation Device
CEN/ISSS WS/E-Sign Draft CWA Group K part 1 – Basic requirements. Version 1
Release 9 (17th September 2003)
[E-Sign 2] Application Interface for Smart Cards used as Secure Signature Creation Device
CEN/ISSS WS/E-Sign Draft CWA Group K part 2 – Additional services. Version 0
Release:19 (12th December 2003)
[IC-ST] Security Target of P5CD144 (NXP) Microcontroller for Smart Cards. Version Rev. 1.3 —4
February 2008
[CC-COMP] Composite product evaluation for Smart Card and similar devices – ISCI-WG1
[JC2.2.1] Java Card 2.2.1 Virtual Machine - 2.2.1 - Oct 2003
[JCRE221] Java CardTM Runtime Environment Specification version 2.2.1, Sun Microsystems, Inc,
2003.
[JCAPI221] Java CardTM APIs specification version 2.2.1, Sun Microsystems, Inc, June 23, 2003.
[GP2.1.1] Global Platform - Card specification v2.1.1 - 2.1.1 - March 2003
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1.5.2 Glossary
CEN workshop agreement (CWA) is a consensus-based specification, drawn up in an open workshop
environment of the European Committee for Standardization (CEN). This Protection Profile (PP) represents
Annex A to the CWA that has been developed by the European Electronic Signature Standardization Initiative
(EESSI) CEN/ISSS electronic signature (E-SIGN) workshop, Area F on secure signature-creation devices
(SSCD).
Certificate means an electronic attestation which links the SVD to a person and confirms the identity of that
person. (defined in the Directive [1], article 2.9)
Certification generation application (CGA) means a collection of application elements which requests
the SVD from the SSCD for generation of the qualified certificate. The CGA stipulates the generation of
a correspondent SCD / SVD pair by the SSCD, if the requested SVD has not been generated by the
SSCD yet. The CGA verifies the authenticity of the SVD by means of
(a) the SSCD proof of correspondence between SCD and SVD and
(b) checking the sender and integrity of the received SVD.
Certification-service-provider (CSP) means an entity or a legal or natural person who issues certificates or
provides other services related to electronic signatures. (defined in the Directive [1], article 2.11)
Data to be signed (DTBS) means the complete electronic data to be signed (including both user message and
signature attributes).
Data to be signed representation (DTBS-representation) means the data sent by the SCA to the TOE for
signing and is
a hash-value of the DTBS or
an intermediate hash-value of a first part of the DTBS and a remaining part of the DTBS or the
DTBS.
The SCA indicates to the TOE the case of DTBS-representation, unless implicitly indicated. The hash-value in
case (a) or the intermediate hash-value in case (b) is calculated by the SCA. The final hash-value in case (b) or
the hash-value in case (c) is calculated by the TOE.
Qualified certificate means a certificate which meets the requirements laid down in Annex I of the Directive [1]
and is provided by a CSP who fulfils the requirements laid down in Annex II of the Directive [1]. (defined in the
Directive [1], article 2.10)
Qualified electronic signature means an advanced signature which is based on a qualified certificate and which
is created by a SSCD according to the Directive [1], article 5, and paragraph 1.
Reference authentication data (RAD) means data persistently stored by the TOE for verification of the
authentication attempt as authorized user.
Secure signature-creation device (SSCD) means configured software or hardware which is used to implement
the SCD and which meets the requirements laid down in Annex III of the Directive [1]. (SSCD is defined in the
Directive [1], article 2.5 and 2.6).
Signatory means a person who holds a SSCD and acts either on his own behalf or on behalf of the natural or
legal person or entity he represents. (defined in the Directive [1], article 2.3)
Signature attributes means additional information that is signed together with the user message.
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Signature-creation application (SCA) means the application used to create an electronic signature, excluding
the SSCD. I.e., the SCA is a collection of application elements
1. to perform the presentation of the DTBS to the signatory prior to the signature process according to
the signatory's decision,
2. to send a DTBS-representation to the TOE, if the signatory indicates by specific non-
misinterpretable input or action the intend to sign,
3. to attach the qualified electronic signature generated by the TOE to the data or provides the qualified
electronic signature as separate data.
Signature-creation data (SCD) means unique data, such as codes or private cryptographic keys, which are used
by the signatory to create an electronic signature. (defined in the Directive [1], article 2.4)
Signature-creation system (SCS) means the overall system that creates an electronic signature. The signature-
creation system consists of the SCA and the SSCD.
Signature-verification data (SVD) means data, such as codes or public cryptographic keys, which are used for
the purpose of verifying an electronic signature. (defined in the Directive [1], article 2.7)
Signed data object (SDO) means the electronic data to which the electronic signature has been attached to or
logically associated with as a method of authentication.
Sub-Referential. Consistent set of software components (Example: test scripts, specification documents,). A
Sub-referential belongs to a Referential.
SSCD provision service means a service that prepares and provides a SSCD to subscribers.
Tip Revision. The latest revision of a line of development (the trunk or a branch)
User means any entity (human user or external IT entity) outside the TOE that interacts with the TOE.
Verification authentication data (VAD) means authentication data provided as input by knowledge or
authentication data derived from user’s biometric characteristics.
1.5.3 Abbreviations
Abreviations
AVA Vulnerability Assessment
CC Common Criteria
CSP certificate-service-provider
DTBS Data To Be Signed
IC Integrated Circuit
OS Operating System
RAD Reference Authentication Data
SAR Security Assurance Requirements
SCD Signature Creation Data
SF Security Function
SFR Security functional requirements
SSCD Secure Signature Creation Device
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ST Security Target
SVD Signature Verification Data
TOE Target Of Evaluation
TSF TOE Security Functionality
VAD Verification Authentication Data
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2 CONFORMANCE CLAIMS
2.1 CC CONFORMANCE CLAIM
This Security Target is built with CC V.3.1
This ST is [CCPART2] extended.
This ST is [CCPART3] conformant.
The TOE includes Integrated Circuit certified with CC V2.3 EAL5+ ALC_DVS.2, AVA_MSU.3; AVA_VLA.4.This
IC has its own ST [IC-ST]. The assets, threats, objectives, SFR and security functions specific to the IC are
described in [IC-ST] and are not repeated in the current ST.
2.2 PP CLAIM, PACKAGE CLAIM
This ST claims a strict compliance with [PP SSCD2] and [PP SSCD3].
[IC-ST] refines the assets, threats, objectives and SFR of [PP/BSI-0002].
This TOE claims conformance to EAL4 augmented (+) with:
• ALC_DVS.2: Sufficiency of security measures.
• AVA_VAN.5: Advanced methodical vulnerability analysis
Equivalence between CC v2.3 EAL4 augmented (+) and CC v3.1 EAL4 augmented (+)
• ADV_IMP.2 (Development – Implementation of the FSP) in CC v2.3 is equivalent to ADV_IMP.1 in CC
v3.1 managed by EAL4 (augmentation not required)
• ALC_DVS.2 (Sufficiency of security measures) augmentation is maintained in CC v3.1 EAL4
augmented
• AVA_MSU.3 (Analysis and testing for insecure states) this CC V3.1 assurance family moved in AGD
families in CC3.1 managed by EAL4
• AVA_VLA.4 (Highly resistant) en CC v2.3 is equivalent to AVA_VAN.5 in CC v3.1, augmentation
maintain in CC v3.1 EAL4 augmented
The strength level for the TOE security functional requirements is “SOF high” (Strength Of Functions high).
2.3 CONFORMANCE RATIONALE
This Security Target is built with CC V3.1 as referenced in External references.
This ST is conformant with [CCPART2] extended due to additional components as stated in Protection Profile
[PP SSCD2], [PP SSCD3] and [PP/BSI-0002].
This ST is conformant with [CCPART3] augmented due to augmentation given in [PP SSCD2], [PP SSCD3]
and [PP/BSI-0002].
[IC-ST] refines the assets, threats, objectives and SFR of [PP/BSI-0002] see BSI certificate and certification
report.
The current ST refines the assets, threats, objectives and SFR of [PP SSCD2], [PP SSCD3] and [BSI PP].
2.4 PP REFINEMENTS
Refinements of [PP/BSI-0002] are described in [IC-ST] and are not repeated here.
The table below shows the functional requirements refined in PP and in ST.
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Functional
requirement
Refined in
[PP SSCD2]
Refined in
[PP SSCD3]
Refined in
ST
FCS_CKM.1 _ X
FCS_CKM.4 _ _ X
FCS_COP.1 X X X
FDP_ACC.1 X X (X)
FDP_ACF.1 X X X
FDP_ETC.1 X X (X)
FDP_ITC.1 X X (X)
FDP_RIP.1 X X (X)
FDP_SDI.2 X X (X)
FDP_UCT.1 X (X)
FDP_UIT.1 X X (X)
FIA_AFL.1 X X X
FIA_ATD.1 X X (X)
FIA_UAU.1 X X X
FIA_UID.1 X X X
FMT_MOF.1 X X (X)
FMT_MSA.1 X X (X)
FMT_MSA.2 NA NA NA
FMT_MSA.3 X X (X)
FMT_MTD.1 X X (X)
FMT_SMF.1 X
FMT_SMR.1 X X (X)
FPT_AMT.11
_ _
FPT_EMSEC.1 _ _ X
FPT_FLS.1 _ _ X
FPT_PHP.1 NA NA NA
FPT_PHP.3 _ _ X
FPT_TST.1 _ _ X
FTP_ITC.1 X X (X)
FTP_TRP.1 X X X
Table 4. PP functional requirements that have been refined
1
This CC2.3 SFR is removed from CC3.1 SFR (no dependencies with FPT_TST in CC 3.1).
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The functional requirements are both refined in the claimed PP and in this ST. This section demonstrates the
compatibility of the refinements done in both documents.
-: No refinement
(X): no additional refinement has been made in the ST.
X: Refinement
NA: the functional requirement requires no refinement.
FCS_CKM.1: Cryptographic key generation
This functional requirement has been refined from [PP SSCD3] with a specific list of approved
algorithms that gives the cryptographic key generation algorithms and key sizes used by the TOE.
FCS_CKM.4: Cryptographic key destruction
This functional requirement is refined from [PP SSCD2] and [PP SSCD3] with a description of the key
destruction method used that follows [no specific standard].
FCS_COP.1: Cryptographic operation
This functional requirement partially refined in [PP SSCD2] and [PP SSCD3] has been completed in the
ST with a specific list of cryptographic algorithms and key sizes that are used by the TOE. Furthermore,
two iterations have been added, one for Hashing and one for the MAC computation.
FDP_ACC.1: Subset access control
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FDP_ACF.1: Security based access control functions
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3]. Additional refinement is
done in the ST.
FDP_ETC.1: Export of user data without security attributes
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FDP_ITC.1: Import of user data without security attributes
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FDP_RIP.1: Subset residual information protection
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FDP_SDI.2: Stored data integrity monitoring and action
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FDP_UCT.1 Basic data exchange confidentiality
This functional requirement is already refined in [PP SSCD2] and no other refinement has been added in
the ST.
FDP_UIT.1: Data exchange integrity
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FIA_AFL.1: Basic authentication failure handling
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This functional requirement is partially refined in [PP SSCD2] and [PP SSCD3]. In the ST the number of
authentication failures has been refined.
FIA_ATD.1: User attribute definition
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FIA_UAU.1: Timing of authentication
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3]. Additional refinement is
done in the ST.
FIA_UID.1: Timing of identification
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3]. Additional refinement is
done in the ST.
FMT_MOF.1: Management of security functions behavior
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FMT_MSA.1: Management of security attributes
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FMT_MSA.2: Secure security attributes
There is no refinement required for this security requirement.
FMT_MSA.3: Static attributes initialization
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FMT_MTD.1: Management of TSF data
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FMT_SMF.1: Specification of Management
This functional requirement is added to [PP SSCD2] and [PP SSCD3] in order to fulfill dependencies of
CC.
FMT_SMR.1: Security roles
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FPT_EMSEC.1: TOE emanation
This functional requirement, extended from CC is not refined in [PP SSCD2] and [PP SSCD3]. It is
entirely refined in the ST.
FPT_FLS.1: Failure with preservation of secure state
This functional requirement is not refined in [PP SSCD2] and [PP SSCD3] and is entirely refined in the
ST.
FPT_PHP.1: Passive detection of physical attacks
There is no refinement required for this security requirement.
FPT_PHP.3: Resistance to physical attack
This functional requirement is not refined in [PP SSCD2] and [PP SSCD3] and is entirely refined in the
ST.
FPT_TST.1: Testing
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This functional requirement is not refined in [PP SSCD2] and [PP SSCD3] and is entirely refined in the
ST.
FTP_ITC.1: Inter-TSF trusted channel
This functional requirement is already refined in [PP SSCD2] and [PP SSCD3] and no other refinement
has been added in the ST.
FTP_TRP.1: Trusted path
This functional requirement is partly refined in [PP SSCD2] and [PP SSCD3]. Additional refinement is
done in the ST.
2.5 PP ADDITIONS
The table below shows the functional requirements refined in PP and in ST.
Addition in ST
Assets -
Threats -
Assumptions -
Organizational Security Policies -
Security objectives for the TOE -
Security objectives for the operational environment -
Security functional requirements X
security assurance requirements -
Security Requirements for the IT Environment -
2.6 ASSURANCE REQUIREMENTS ADDITIONAL TO THE PP
There is no assurance requirement, which is not in [PP SSCD2], [PP SSCD3] or [PP/BSI-0002].
2.7 PP CLAIMS RATIONALE
This security target presents all PP SSCD Type 2 and Type 3 threats, assumptions, objectives, functional
requirements and assurance measures.
The additional SFR FMT_SMF.1.1 (for CCv3.1) does not introduce contradiction.
There are no additional assurance measures to PP SSCD Type 2 and Type 3. The strength of function claimed
is high, and the claimed level is EAL4+ as required by the claimed PP. The IC security functions used by the
platform also claim high level and the used IC is compliant to level EAL4+. Therefore, no inconsistency is
introduced and the PP SSCD Type 2 & 3 claim is fulfilled.
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No disclosure to a third party without prior written consent of Gemalto
3 SECURITY PROBLEM DEFINITION
This section describes the security aspects of the TOE environment and addresses the description of the
assets to be protected, the threats, the organizational security policies and the assumptions.
Remark: This chapter “Security problem definition” in CC V3.1 is equivalent to “TOE security environment” in
CC V2.3 and in PP SSCD [PP SSCD2], [PP SSCD3].
3.1 DIGITAL SIGNATURE ASSETS
The assets of the TOE are those defined in [PP SSCD2], [PP SSCD3] and [PP/BSI-0002].
This Security Target deals with the assets of [PP SSCD2] and [PP SSCD3]. The assets of [PP/BSI-0002] are
studied in [IC-ST].
D.SCD
SCD: private key used to perform an electronic signature operation
(confidentiality of the SCD must be maintained).
D.SVD
SVD: public key linked to the SCD and used to perform electronic signature
verification (integrity of the SVD when it is exported must be maintained).
D.DTBS
DTBS and DTBS-representation: set of data or its representation which is
intended to be signed (their integrity must be maintained)
D.VAD
VAD: PIN code data entered by the End User to perform a signature operation
(confidentiality and authenticity of the VAD as needed by the authentication
method employed)
D.RAD
RAD: Reference PIN code authentication reference used to identify and
authenticate the End User (Integrity and confidentiality of RAD must be
maintained)
D.SSCD
Signature-creation function of the SSCD using the SCD: (The quality of the
function must be maintained so that it can participate to the legal validity of
electronic signatures)
D.SIG
Electronic signature: (enforceability of electronic signatures must be assured).
3.2 DIGITAL SIGNATURE SUBJECTS
S.User End user of the TOE which can be identified as S.Admin or S.Signatory.
S.Admin
User who is in charge to perform the TOE initialization, TOE personalization or
other TOE administrative functions.
S.Signatory
User who holds the TOE and uses it on his own behalf or on behalf of the
natural or legal person or entity he represents.
S.OFFCARD
Attacker. A human or process acting on his behalf being located outside the
TOE. The main goal of the S.OFFCARD attacker is to access Application
sensitive information. The attacker has a high level potential attack and
knows no secret.
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 Gemalto Public  Gemalto Private  Gemalto Restricted  Gemalto Confidential <code>  Gemalto Secret .
No disclosure to a third party without prior written consent of Gemalto
3.3 DIGITAL SIGNATURE THREATS
T.Hack_Phys
Physical attacks through the TOE interfaces.
An attacker S.OFFCARD interacts with the TOE interfaces to exploit
vulnerabilities to gain fraudulent access to the Assets.
T.SCD_Divulg
Storing, copying, and releasing of signature-creation D.SCD.
An attacker S.OFFCARD can store, copy the SCDD.SCD outside the TOE. An
attacker S.OFFCARD can release the SCD D.SCD during generation, storage
and use for signature-creation in the TOE.
T.SCD_Derive
Derive the signature-creation data D.SCD.
An attacker S.OFFCARD derives the SCD D.SCD from public known data,
such as SVD corresponding to the SCD or signatures created by means of the
SCD or any other data communicated outside the TOE, which is a threat
against the secrecy of the SCD.
T.Sig_Forgery
Forgery of electronic signature D.SIG.
An attacker S.OFFCARD forges the signed data object maybe together with its
electronic signature created by the TOE and the violation of the integrity of the
signed data object is not detectable by the signatory or by third parties. The
signature generated by the TOE is subject to deliberate attacks by experts
possessing a high attack potential with advanced knowledge of security
principles and concepts employed by the TOE.
T.Sig_Repud
Repudiation of signatures D.SIG.
If an attacker S.OFFCARD can successfully threaten any of the assets, then
the non repudiation of the electronic signature is compromised.
The signatory is able to deny having signed data using the SCD in the TOE
under his control even if the signature is successfully verified with the SVD
contained in his un-revoked certificate.
T.SVD_Forgery
Forgery of the signature- verification data D.SVD.
An attacker S.OFFCARD forges the SVD D.SVD presented by the TOE. This
result in loss of SVD integrity in the certificate of the signatory.
T.DTBS_Forgery
Forgery of the DTBS-representation D.DTBS.
An attacker S.OFFCARD modifies the DTBS-representation D.DTBS. sent by
the SCA. Thus the DTBS-representation used by the TOE for signing does not
match the DTBS the signatory intends to sign.
T.SigF_Misuse
Misuse of the Signature-Creation function of the TOE
An attacker S.OFFCARD misuses the signature-creation function of the TOE
to create SDO for data the signatory has not decided to sign. The TOE is
subject to deliberate attacks by experts possessing a high attack potential with
advanced knowledge of security principles and concepts employed by the
TOE.
3.4 DIGITAL SIGNATURE ASSUMPTIONS
This section defines assumptions related to the Digital Signature application as stated in PP SSCD and as
stated in [PP/BSI-0002] for composite evaluation.
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No disclosure to a third party without prior written consent of Gemalto
A.CGA
Trustworthy certification-generation application
The CGA protects the authenticity of the signatory’s name and the SVD in
the qualified certificate by an advanced signature of the CSP.
A.SCA
Trustworthy signature-creation application
The signatory uses only a trustworthy SCA. The SCA generates and sends
the DTBS-representation of data the signatory wishes to sign in a form
appropriate for signing by the TOE.
A.SCD_Generate (type2)
Trustworthy SCD/SVD generation.
If a party other than the signatory generates the SCD/SVD-pair of a
signatory, then
(a) this party will use a SSCD for SCD/SVD-generation,
(b) confidentiality of the SCD will be guaranteed until the SCD is under the
sole control of the signatory and
(c) the SCD will not be used for signature-creation until the SCD is under
the sole control of the signatory.
(d) The generation of the SCD/SVD is invoked by authorised users only
(e) The SSCD Type1 ensures the authenticity of the SVD it has created
and exported.
3.5 ORGANIZATIONAL SECURITY POLICIES
This section defines OSPs related to the Digital Signature application as stated in PP SSCD3.
P.CSP_Qcert
Qualified certificate.
The CSP uses a trustworthy CGA to generate the qualified certificate for the
SVD generated by the SSCD. The qualified certificates contains at least the
elements defined in Annex I of the Directive [DIRECTIVE], i.e., inter alias the
name of the signatory and the SVD matching the SCD implemented in the
TOE under sole control of the signatory. The CSP ensures that the use of the
TOE is evident with signatures through the certificate or other publicly
available information.
P.Qsign
Qualified electronic signatures.
The signatory uses a signature-creation system to sign data with qualified
electronic signatures.
The DTBS are presented to the signatory by the SCA. The qualified
electronic signature is based on a qualified certificate and is created by a
SSCD.
P.Sigy_SSCD
TOE as secure signature-creation device.
The TOE stores the SCD used for signature creation under sole control of
the signatory. The SCD used for signature generation can practically occur
only once.
4 SECURITY OBJECTIVES
The security objectives in this Security Target are those named and described in [PP SSCD2] and [PP
SSCD3].
They cover the following aspects:
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No disclosure to a third party without prior written consent of Gemalto
- The security objectives for the TOE,
- The security objectives for the environment.
The security objectives stated in [PP/BSI-0002] can be found in [IC-ST].
4.1 SECURITY OBJECTIVES FOR THE TOE
OT.EMSEC_Design
Provide physical emanations security
Design and build the TOE in such a way as to control the production of
intelligible emanations within specified limits.
OT.Lifecycle_Security
Lifecycle security.
The TOE shall detect flaws during the initialization, personalization and
operational usage. The TOE shall provide safe destruction techniques for
the SCD in case of re-generation or re-import.
OT.SCD_Secrecy
Secrecy of the signature-creation data.
The secrecy of the SCD (used for signature generation) is reasonably
assured against attacks with a high attack potential.
OT.SCD_SVD_Corresp
Correspondence between SVD and SCD.
The TOE shall ensure the correspondence between the SVD and the
SCD. The TOE shall verify on demand the correspondence between the
SCD stored in the TOE and the SVD if it has been sent to the TOE.
OT.SVD_Auth_TOE
TOE ensures authenticity of SVD.
The TOE provides means to enable the CGA to verify the authenticity
SVD that has been exported by that TOE.
OT.Tamper_ID
Tamper detection.
The TOE shall provide system features that detect physical tampering of
a system component, and use those features to limit security breaches.
OT.Tamper_Resistance
Tamper resistance.
The TOE shall prevent or resist physical tampering with specified system
devices and components.
OT.Init (type 3)
Secure SCD SVD generation.
The TOE provides security features to ensure that the generation of the
SCD and the SVD is invoked by authorized users only.
OT.SCD_Unique (type 3)
Uniqueness of the signature-creation data
The TOE shall ensure the cryptographic quality of the SCD/ SVD pair for
the qualified electronic signature. The SCD used for signature generation
can practically occur only once and cannot be reconstructed from the
SVD. In that context ‘practically occur once’ means that the probability of
equal SCDs is negligible low.
OT.SCD_Transfer (Type 2)
Secure transfer of SCD between SSCD.
The TOE shall ensure the confidentiality of the SCD transferred between
SSCDs.
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No disclosure to a third party without prior written consent of Gemalto
OT.DTBS_Integrity_TOE
Verification of the DTBS-representation integrity
The TOE shall verify that the DTBS-representation received from the SCA
has not been altered in transit between the SCA and the TOE. The TOE
itself shall ensure that the DTBS-representation is not altered by the TOE
as well. Note, that this does not conflict with the signature-creation
process where the DTBS itself could be hashed by the TOE.
OT.Sigy_SigF
Signature generation function for the legitimate signatory only.
The TOE provides the signature generation function for the legitimate
signatory only and protects SCD against the use of others. The TOE shall
resist attacks with high attack potential.
OT.Sig_Secure
Cryptographic security of the electronic signature
The TOE generates electronic signatures that cannot be forged without
knowledge of the SCD through robust encryption techniques. The SCD
cannot be reconstructed using the electronic signatures. The electronic
signatures shall be resistant against these attacks, even when executed
with a high attack potential.
4.2 SECURITY OBJECTIVES FOR THE OPERATIONAL ENVIRONMENT
This section describes the security objectives for the environment.
The IT environment of the TOE is composed of the Certification Generation Application (CGA) and the
Signature Creation Application (SCA).
Security Objectives Description
OE.SCD_SVD_Corresp
(type 2)
Correspondence between SVD and SCD
The SSCD Type1 shall ensure the correspondence between the SVD and the
SCD. The SSVD Type1 shall prove the correspondence between the SCD sent
to the TOE and the SVD sent to the CGA or TOE.
OE.SCD_Transfer (type 2) Secure transfer of SCD between SSCD
The SSCD Type1 shall ensure the confidentiality of the SCD transferred to the
TOE. The SSCD Type1 shall prevent the export of a SCD that already has
been used for signature generation by the SSCD Type1. The SCD shall be
deleted from the SSCD Type1 whenever it is exported into the TOE.
OE.SCD_Unique (type 2) Uniqueness of the signature-creation data
The SSCD Type1 shall ensure the cryptographic quality of the SCD/SVD pair
for the qualified electronic signature. The SCD used for signature generation
can practically occur only once and cannot be reconstructed from the SVD. In
that context ‘practically occur once’ means that the probability of equal SCDs is
negligible low.
OE.CGA_Qcert Generation of qualified certificates
The CGA generates qualified certificates which include inter alias
the name of the signatory controlling the TOE,
the SVD matching the SCD implemented in the TOE under sole control of the
signatory,
the advanced signature of the CSP.
OE.SVD_AUTH_CGA CGA verifies the authenticity of the SVD
The CGA verifies that the SSCD is the sender of the received SVD and the
integrity of the received SVD. The CGA verifies the correspondence between
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 Gemalto Public  Gemalto Private  Gemalto Restricted  Gemalto Confidential <code>  Gemalto Secret .
No disclosure to a third party without prior written consent of Gemalto
the SCD in the SSCD of the signatory and the SVD in the qualified certificate.
OE.HI_VAD Protection of the VAD
If an external device provides the human interface for user authentication, this
device will ensure confidentiality and integrity of the VAD as needed by the
authentication method employed.
OE.SCA_Data_Intend Data intended to be signed
The SCA
(a) generates the DTBS-representation of the data that has been presented as
DTBS and which the signatory intends to sign in a form which is appropriate for
signing by the TOE,
(b) sends the DTBS-representation to the TOE and enables verification of the
integrity of DTBS-representation by the TOE,
(c) attaches the signature produced by the TOE to the data or provides it
separately .
4.3 SECURITY OBJECTIVES RATIONALE
4.3.1 Threats
T.Hack_Phys (Exploitation of physical vulnerabilities) deals with physical attacks exploiting physical
vulnerabilities of the TOE. OT.SCD_Secrecy preserves the secrecy of the SCD.
OT.EMSEC_Design counters physical attacks through the TOE interfaces or observation of TOE
emanations. OT.Tamper_ID and OT.Tamper_Resistance counter the threat T.Hack_Phys by detecting and
by resisting tamper attacks.
T.SCD_Divulg (Storing and copying and releasing of the signature-creation data) addresses the threat
against the legal validity of electronic signature due to storage and copying of SCD outside the TOE, as
expressed in the Directive [1], recital (18). This threat is countered by OT.SCD_secrecy, which assures the
secrecy of the SCD used for signature generation.
OT.SCD_Transfer and OE.SCD_Transfer ensure the confidentiality of the SCD transferred between
SSCDs.
T.SCD_Derive (Derive the signature-creation data) deals with attacks on the SCD via public known data
produced by the TOE. This threat is countered by OE.SCD_Unique that provides cryptographic secure
generation of the SCD/SVD pair. OT.Sig_Secure ensures cryptographic secure electronic signatures.
T.Sig_Forgery (Forgery of the electronic signature) deals with non-detectable forgery of the electronic
signature. This threat is in general addressed by OT.Sig_Secure (Cryptographic security of the electronic
signature), OE.SCA_Data_Intend (SCA sends representation of data intended to be signed),
OE.CGA_QCert (Generation of qualified certificates), OT.SCD_SVD_Corresp (Correspondence between
SVD and SCD), OT.SVD_Auth_TOE (TOE ensures authenticity of the SVD), OE.SVD_Auth_CGA (CGA
proves the authenticity of the SVD), OT.SCD_Secrecy (Secrecy of the signature-creation data),
OT.SCD_Transfer (Secure transfer of SCD between SSCD), OT.EMSEC_Design (Provide physical
emanations security), OT.Tamper_ID (Tamper detection), OT.Tamper_Resistance (Tamper resistance)
and OT.Lifecycle_Security (Lifecycle security), as follows.
OT.Sig_Secure ensures by means of robust encryption techniques that the signed data and the electronic
signature are securely linked together. OE.SCA_Data_Intend provides that the methods used by the SCA
(and therefore by the verifier) for the generation of the DTBS-representation is appropriate for the
cryptographic methods employed to generate the electronic signature. The combination of OE.CGA_QCert,
OT.SCD_SVD_Corresp, OT.SVD_Auth_TOE, and OE.SVD_Auth_CGA provides the integrity and
authenticity of the SVD that is used by the signature verification process. OT.Sig_Secure,
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 Gemalto Public  Gemalto Private  Gemalto Restricted  Gemalto Confidential <code>  Gemalto Secret .
No disclosure to a third party without prior written consent of Gemalto
OT.SCD_Secrecy, OT.SCD_Transfer, OT.EMSEC_Design, OT.Tamper_ID, OT.Tamper_Resistance, and
OT.Lifecycle_Security ensure the confidentiality of the SCD implemented in the signatory's SSCD and thus
prevent forgery of the electronic signature by means of knowledge of the SCD.
T.Sig_Repud (Repudiation of electronic signatures) deals with the repudiation of signed data by the
signatory, although the electronic signature is successfully verified with the SVD contained in his un-revoked
certificate. This threat is in general addressed by OE.CGA_QCert (Generation of qualified certificates),
OT.SVD_Auth_TOE (TOE ensures authenticity of the SVD), OE.SVD_Auth_CGA (CGA proves the
authenticity of the SVD), OT.SCD_SVD_Corresp (Correspondence between SVD and SCD),
OT.SCD_Unique (Uniqueness of the signature creation data), OT.SCD_Transfer (Secure transfer of SCD
between SSCD), OT.SCD_Secrecy (Secrecy of the signature-creation data), OT.EMSEC_Design (Provide
physical emanations security), OT.Tamper_ID (Tamper detection), OT.Tamper_Resistance (Tamper
resistance), OT.Lifecycle_Security (Lifecycle security), OT.Sigy_SigF (Signature generation function for the
legitimate signatory only), OT.Sig_Secure (Cryptographic security of the electronic signature),
OE.SCA_Data_Intend (SCA sends representation of data intended to be signed) and
OT.DTBS_Integrity_TOE (Verification of the DTBS-representation integrity).
OE.CGA_QCert ensures qualified certificates which allow to identify the signatory and thus to extract the
SVD of the signatory. OE.CGA_QCert, OT.SVD_Auth_TOE and OE.SVD_Auth_CGA ensure the integrity of
the SVD. OE.CGA_QCert and OT.SCD_SVD_Corresp ensure that the SVD in the certificate correspond to
the SCD that is implemented by the SSCD of the signatory. OT.SCD_Unique provides that the signatory's
SCD can practically occur just once. OT.Sig_Secure, OT.SCD_Transfer, OT.SCD_Secrecy,
OT.Tamper_ID, OT.Tamper_Resistance, OT.EMSEC_Design, and OT.Lifecycle_Security ensure the
confidentiality of the SCD implemented in the signatory's SSCD. OT.Sigy_SigF provides that only the
signatory may use the TOE for signature generation. OT.Sig_Secure ensures by means of robust
cryptographic techniques that valid electronic signatures may only be generated by employing the SCD
corresponding to the SVD that is used for signature verification and only for the signed data.
OE.SCA_Data_Intend and OT.DTBS_Integrity_TOE ensure that the TOE generates electronic signatures
only for DTBS-representations that the signatory has decided to sign.
T.SVD_Forgery (Forgery of the signature-verification data) deals with the forgery of the SVD exported by
the TOE to the CGA for the generation of the certificate. T.SVD_Forgery is addressed by
OT.SVD_Auth_TOE, which ensures that the TOE sends the SVD in a verifiable form to the CGA, as well as
by OE.SVD_Auth_CGA, which provides verification of SVD authenticity by the CGA.
T.DTBS_Forgery (Forgery of the DTBS-representation) addresses the threat arising from modifications of
the DTBS-representation sent to the TOE for signing which then does not correspond to the DTBS-
representation corresponding to the DTBS the signatory intends to sign. The TOE counters this threat by
the means of OT.DTBS_Integrity_TOE by verifying the integrity of the DTBS-representation. The TOE IT
environment addresses T.DTBS_Forgery by the means of OE.SCA_Data_Indent.
T.SigF_Misuse (Misuse of the signature-creation function of the TOE) addresses the threat of misuse of
the TOE signature-creation function to create SDO by others than the signatory to create SDO for data the
signatory has not decided to sign, as required by the Directive [1], Annex III, paragraph 1, literal (c). This
threat is addressed by the OT.Sigy_SigF (Signature generation function for the legitimate signatory only),
OE.SCA_Data_Intend (Data intended to be signed), OT.DTBS_Integrity_TOE (Verification of the DTBS-
representation integrity), and OE.HI_VAD (Protection of the VAD) as follows:
OT.Sigy_SigF ensures that the TOE provides the signature-generation function for the legitimate signatory
only. OE.SCA_Data_Intend ensures that the SCA sends the DTBS-representation only for data the
signatory intends to sign. The combination of OT.DTBS_Integrity_TOE and OE.SCA_Data_Intend counters
the misuse of the signature generation function by means of manipulation of the channel between the SCA
and the TOE. If the SCA provides the human interface for the user authentication, OE.HI_VAD provides
confidentiality and integrity of the VAD as needed by the authentication method employed.
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No disclosure to a third party without prior written consent of Gemalto
4.3.2 Assumptions
A.CGA (Trustworthy certification-generation application) establishes the protection of the authenticity of
the signatory's name and the SVD in the qualified certificate by the advanced signature of the CSP by
means of the CGA. This is addressed by OE.CGA_QCert (Generation of qualified certificates), which
ensures the generation of qualified certificates, and by OE.SVD_Auth_CGA (CGA proves the authenticity of
the SVD), which ensures the verification of the integrity of the received SVD and the correspondence
between the SVD and the SCD that is implemented by the SSCD of the signatory.
A.SCA (Trustworthy signature-creation application) establishes the trustworthiness of the SCA according
to the generation of DTBS-representation. This is addressed by OE.SCA_Data_Intend (Data intended to be
signed) which ensures that the SCA generates the DTBS-representation of the data that has been
presented to the signatory as DTBS and which the signatory intends to sign in a form which is appropriate
for being signed by the TOE.
A.SCD_Generate Trustworthy SCD/SVD generation establishes a trustworthy SCD/SVD pair. This means
that the SCD must be unique, objective met by OE.SCD_Unique, that the SCD and the SVD must
correspond, objective met by OE.SCD_SVD_Corresp. The secrecy of the SCD must be maintained while it
is transferred to the TOE before being deleted, OE.SCD_Transfer. (Remark: type 2 only).
4.3.2.1 Additional
4.3.3 Organisational security policies
P.CSP_QCert (CSP generates qualified certificates) establishes the qualified certificate for the signatory
and provides that the SVD matches the SCD that is implemented in the SSCD under sole control of this
signatory. On SCD/SVD correspondence, this OSP is addressed by OT.SCD_SVD_Corresp and
OE.SCD_SVD_Corresp. In the IT environment, this OSP is addressed by OE.CGA_QCert for generation of
qualified certificates by the CGA, respectively.
P.QSign (Qualified electronic signatures) provides that the TOE and the SCA may be employed to sign data
with qualified electronic signatures, as defined by the Directive [1], article 5, paragraph 1. Directive [1],
recital (15) refers to SSCDs to ensure the functionality of advanced signatures. The requirement of qualified
electronic signatures being based on qualified certificates is addressed by OE.CGA_QCert.
OE.SCA_Data_Intend ensures that the SCA presents the DTBS to the signatory and sends the DTBS-
representation to the TOE. OT.Sig_Secure and OT.Sigy_SigF address the generation of advanced
signatures by the TOE.
P.Sigy_SSCD (TOE as secure signature-creation device) establishes the TOE as secure signature-creation
device of the signatory with practically unique SCD. This OSP is addressed by OT.Sigy_SigF that ensures
that the SCD is under sole control of the signatory, and OE.SCD_Unique that ensures that the
cryptographic quality of the SCD/SVD pair for the qualified electronic signature.
5 EXTENDED COMPONENTS DEFINITION
The additional family FPT_EMSEC (TOE Emanation) of the Class FPT (Protection of the TSF) is defined here
to describe the IT security functional requirements of the TOE.
The TOE shall prevent attacks against the SCD and other secret data where the attack is based on external
observable physical phenomena of the TOE.
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No disclosure to a third party without prior written consent of Gemalto
Examples of such attacks are evaluation of TOE’s electromagnetic radiation, simple power analysis (SPA),
differential power analysis (DPA), timing attacks, etc. This family describes the functional requirements for the
limitation of intelligible emanations.
FPT_EMSEC TOE Emanation
Family behavior
This family defines requirements to mitigate intelligible emanations.
Component leveling:
FPT_EMSEC.1 TOE Emanation has two constituents:
• FPT_EMSEC.1.1 Limit of Emissions requires to not emit intelligible emissions enabling access to TSF
data or user data.
• FPT_EMSEC.1.2 Interface Emanation requires not emit interface emanation enabling
access to TSF data or user data.
Management: FPT_EMSEC.1
There are no management activities foreseen.
Audit: FPT_EMSEC.1
There are no actions identified that should be auditable if FAU_GEN Security audit data generation is included
in the PP.
FPT_EMSEC.1 TOE Emanation
• FPT_EMSEC.1.1 The TOE shall not emit [assignment: types of emissions] in excess of [assignment:
specified limits] enabling access to [assignment: list of types of TSF data] and [assignment: list of
types of user data].
• FPT_EMSEC.1.2 The TSF shall ensure [assignment: type of users] are unable to use the following
interface [assignment: type of connection] to gain access to [assignment: list of types of TSF data] and
[assignment: list of types of user data].
Hierarchical to: No other components.
Dependencies: No other components.
FPT_EMSEC TOE Emanation 1
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No disclosure to a third party without prior written consent of Gemalto
6 SECURITY REQUIREMENTS
6.1 TOE SECURITY FUNCTIONAL REQUIREMENTS
This chapter defines the security functional requirements for the TOE using functional requirements
components as specified in [PP SSCD2] and [PP SSCD3].
[IC-ST] deals with the security functional requirements of [PP/BSI-0002].
6.1.1 Security functional requirements list
Identification Description
FCS Cryptographic support
FCS_CKM.1 Cryptographic key generation
FCS_CKM.4 Cryptographic key destruction
FCS_COP.1 Cryptographic operation
FDP User data protection
FDP_ACC.1 Subset Access control
FDP_ACF.1 Security attributes based access control
FDP_ETC.1 Export of user data without security attributes
FDP_ITC.1 Import of User Data without security attributes
FDP_RIP.1 Subset residual information protection
FDP_SDI.2 Stored data integrity monitoring and action
FDP_UCT.1 Basic data exchange confidentiality
FDP_UIT.1 Basic data exchange integrity
FIA Identification and Authentication
FIA_AFL.1 Authentication failure handling
FIA_ATD.1 User attribute definition
FIA_UAU.1 Timing of authentication
FIA_UID.1 Timing of identification
FMT Security management
FMT_MOF.1 Management of security function behavior
FMT_MSA.1 Management of security attributes
FMT_MSA.2 Secure security attributes
FMT_MSA.3 Static attribute initialization
FMT_MTD.1 Management of TSF data
FMT_SMF.1 Specification of management functions
FMT_SMR.1 Security roles
FPT Protection of the TOE Security function
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No disclosure to a third party without prior written consent of Gemalto
FPT_AMT.1 Abstract machine testing 2
FPT_EMSEC.1 TOE Emanation
FPT_FLS.1 Failure with preservation of secure state
FPT_PHP.1 Passive detection of physical attack
FPT_PHP.3 Resistance to physical attack
FPT_TST.1 TSF testing
FTP Trusted path/Channel
FTP_ITC.1 Inter-TSF trusted channel
FTP_TRP.1 TOE Trusted path
Table 5. IAS Classic security functional requirements list
6.1.2 FCS – Cryptographic support
Remark: To be in the context of the French qualification RSA key shall use 1536 or 2048 bits.
6.1.2.1 FCS_CKM cryptographic key management
FCS_CKM.1 Cryptographic key generation
FCS_CKM.1/RSA
FCS_CKM.1/RSA The TSF shall generate cryptographic keys in accordance with a specified
cryptographic key generation algorithm [RSA key generation] and specified
cryptographic key sizes [1024, 1536 and 2048 bits] that meet the following: [no
standard].
Application note: Type 3 only.
Remark: Link with Initialization SFP.
FCS_CKM.1.1/DH
FCS_CKM.1/DH The TSF shall generate cryptographic keys in accordance with a specified
cryptographic key generation algorithm [Diffie-Helman 1024, 1536, 2048] and
specified cryptographic key sizes [160 bits] that meet the following: no standard.
Remark: DH authentication scheme see chapter 5.2.3 of [SRS];
FCS_CKM.1.1/ TDES
FCS_CKM.1/ TDES The TSF shall generate cryptographic keys in accordance with a specified
cryptographic key generation algorithm [SRS chapter 7.1] and specified
cryptographic key sizes [112 bits] that meet the following: [no standard].
FCS_CKM.4 Cryptographic key destruction
FCS_CKM.4/SCD
2
This CC2.3 SFR is removed from CC3.1 SFR (no dependencies with FPT_TST in CC 3.1).
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 Gemalto Public  Gemalto Private  Gemalto Restricted  Gemalto Confidential <code>  Gemalto Secret .
No disclosure to a third party without prior written consent of Gemalto
FCS_CKM.4.1/SCD The TSF shall destroy cryptographic keys in accordance with a specified
cryptographic key destruction method [overwrite the keys] hat meets the following:
[no standard].
Application note (refined):
The cryptographic key SCD will be destroyed on demand of the Signatory.
The destruction of the SCD is mandatory before the SCD/SVD pair is re-imported into the TOE.(Type 2)
The destruction of the SCD is mandatory before the SCD/SVD pair is re-generated by the TOE.(Type 3)
Remark: Link with SCD destruction SFP.
6.1.2.2 FCS_COP Cryptographic operation
FCS_COP.1 Cryptographic operation
FCS_COP.1/CORRESP
FCS_COP.1.1/
CORRESP
The TSF shall perform [SCD / SVD correspondence proof] in accordance with a
specified cryptographic algorithm [RSA key generation] and cryptographic key
sizes [1024, 1536 and 2048 bits] that meet the following: [no standard].
Application note:
When the key pair is generated on card, the key generation process ensures that the public key corresponds to
the private key.( Link with Initialization SFR)
When the SCD is input in the card, the card does not manage the SVD. The SVD or the corresponding
certificate can be input in a standard file for future use by the application. But the card does not even know the
content of the file. (Link with SVD transfer SFP)
FCS_COP.1/SIGNING
FCS_COP.1.1/
SIGNING
The TSF shall perform [Digital signature-generation] in accordance with a
specified cryptographic algorithm [RSA_SHA_PKCS#1] and cryptographic key
sizes [1024, 1536 and 2048 bits]] that meet the following: [RSA PKCS #1, using
SHA-1 or SHA-256].
Remark: Link with Signature creation SFP
FCS_COP.1/MAC
FCS_COP.1.1/
MAC
The TSF shall perform secure messaging – message authentication code in
accordance with a specified cryptographic algorithm ANSI X9.19 (Retail MAC)
and cryptographic key sizes 112 bits that meet the following: [SRS chapter 7.1]
FCS_COP.1/TDES Cryptographic operation
FCS_COP.1.1/
TDES
The TSF shall perform [TDES encryption and decryption] in accordance with a
specified cryptographic algorithm [TDES-CBC] and cryptographic key sizes [112
bits for TDES 2 keys] that meet the following: [FIPS 46-3].
Application note:
The TOE can also encrypt and decrypt using DES algorithm with 56 bits key, but this is to be considered as a
service. The DES algorithm is no longer considered as resistant to high level attacks.
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No disclosure to a third party without prior written consent of Gemalto
FCS_COP.1/SHA Cryptographic operation
FCS_COP.1.1/
SHA-1
The TSF shall perform data hashing in accordance with a specified
cryptographic algorithm SHA-1, SHA-256 and cryptographic key sizes none that
meet the following: FIPS 180-2.
Application note:
This cryptographic operation does not use key.
FCS_COP.1/RNG Cryptographic operation
FCS_COP.1.1/
RNG
The TSF shall perform Random Number Generation in accordance with a
specified cryptographic algorithm Random Number Generator and
cryptographic key sizes None that meet the following: ANSI X9.17 Appendix C.
Application note:
This cryptographic operation does not use key.
6.1.3 FDP: User data protection
6.1.3.1 FDP_ACC Access Control policy
FDP_ACC.1 Subset access control
FDP_ACC.1/Initialization SFP
FDP_ACC.1.1/
Initialization SFP
The TSF shall enforce the [Initialization SFP] on [Generation of SCD/SVD
pair by User].
Application note: Type 3 only.
FDP_ACC.1/SVD Transfer SFP
FDP_ACC.1.1/ SVD
Transfer SFP
The TSF shall enforce the [SVD Transfer SFP] on [import and export of
SVD by User].
Application note:
When SCD is imported into the TOE, FDP_ACC.1/SVD Transfer SFP will be required only, if the TOE is to
import the SVD from a SSCD Type1 so it will be exported to the CGA for certification. This is not the case in
this TOE. (Type 2)
When SCD is generated in the TOE, FDP_ACC.1/SVD Transfer SFP will be required to export the SVD to the
CGA for certification. (Type 3).
FDP_ACC.1/SCD Import SFP
FDP_ACC.1.1/ SCD The TSF shall enforce the [SCD Import SFP] on [Import of SCD by User].
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No disclosure to a third party without prior written consent of Gemalto
Import SFP
Application note: Type 2 only.
FDP_ACC.1/Personalization SFP
FDP_ACC.1.1/
Personalization SFP
The TSF shall enforce the [Personalization SFP] on [Creation of RAD by
Administrator].
FDP_ACC.1/Signature-creation SFP
FDP_ACC.1.1/ Signature-
creation SFP
The TSF shall enforce the [Signature-creation SFP] on [Sending of DTBS-
representation by SCA] and [Signing of DTBS-representation by
Signatory].
6.1.3.2 FDP_ACF access control function
FDP_ACF.1 Security attributes based access control
The security attributes for the subjects, TOE components and related status are:
Groups of security attributes
[USER, SUBJECT OR OBJECT THE
ATTRIBUTE IS ASSOCIATED WITH]
ATTRIBUTES ATTRIBUTES STATUS
GENERAL ATTRIBUTE GROUP
[User] ROLE ADMINISTRATOR,
SIGNATORY
INITIALIZATION ATTRIBUTE GROUP
[USER] SCD/SVD MANAGEMENT AUTHORIZED / NOT
AUTHORIZED
[SCD] SECURE SCD IMPORT ALLOWED NO/YES
SIGNATURE-CREATION ATTRIBUTE GROUP
[SCD ] SCD OPERATIONAL NO/YES
[DTBS] SENT BY AN AUTHORIZED SCA NO/YES
Refinement:
The rules for specific functions that implement access control SFP defined in FDP_ACC.1 are the following:
FDP_ACF.1/Initialization SFP
FDP_ACF.1.1/
Initialization SFP
The TSF shall enforce the [Initialization SFP] to objects based on [General
attribute group] and [Initialization attribute group].
FDP_ACF.1.2/
Initialization SFP
The TSF shall enforce the following rules to determine if an operation among
controlled subjects and controlled objects is allowed:
The user with the security attribute “role” set to “Administrator” or set to
“Signatory” and with the security attribute “SCD / SVD management” set to
“authorized” is allowed to generate SCD/SVD pair.
FDP_ACF.1.3/
Initialization SFP
The TSF shall explicitly authorize access of subjects to objects based on the
following additional rules: [none]
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No disclosure to a third party without prior written consent of Gemalto
FDP_ACF.1.4/
Initialization SFP
The TSF shall explicitly deny access of subjects to objects based on the rule:
The user with the security attribute “role” set to “Administrator” or set to
“Signatory” and with the security attribute “SCD / SVD management” set to “not
authorized” is not allowed to generate SCD/SVD pair.
Application note: Type 3 only.
FDP_ACF.1/SVD Transfer SFP
FDP_ACF.1.1/
SVD Transfer SFP
The TSF shall enforce the [SVD Transfer SFP] to objects based on [General
attribute group]
FDP_ACF.1.2/
SVD Transfer SFP
The TSF shall enforce the following rules to determine if an operation among
controlled subjects and controlled objects is allowed:
The user with the security attribute “role” set to “Administrator” or to “Signatory”
is allowed to export SVD.
FDP_ACF.1.3/
SVD Transfer SFP
The TSF shall explicitly authorize access of subjects to objects based on the
following additional rules [none].
FDP_ACF.1.4/
SVD Transfer SFP
The TSF shall explicitly deny access of subjects to objects based on the rule:
[none].
Application note:
FDP_ACF.1/SVD Transfer SFP will be required only, if the TOE holds the SVD and the SVD is exported to the
CGA for certification.
FDP_ACF.1/SCD Import SFP
FDP_ACF.1.1/ SCD
Import SFP
The TSF shall enforce the [SCD Import SFP] to objects based on [General
attribute group] and [Initialization attribute group].
FDP_ACF.1.2/
SCD Import SFP
The TSF shall enforce the following rules to determine if an operation among
controlled subjects and controlled objects is allowed:
The user with the security attribute “role” set to “Administrator” or to “Signatory”
and with the security attribute “SCD / SVD management” set to “authorized” is
allowed to import SCD if the security attribute “secure SCD import allowed” is
set to “yes”.
FDP_ACF.1.3/ SCD
Import SFP
The TSF shall explicitly Authorize access of subjects to objects based on the
following additional rules [none].
FDP_ACF.1.4/ SCD
Import SFP
The TSF shall explicitly deny access of subjects to objects based on the rule:
The user with the security attribute “role” set to “Administrator” or to “Signatory”
and with the security attribute “SCD / SVD management” set to “not authorized”
is not allowed to import SCD if the security attribute “secure SCD import
allowed” is set to “yes”.
The user with the security attribute “role” set to “Administrator” or to “Signatory”
and with the security attribute “SCD / SVD management” set to “authorized” is
not allowed to import SCD if the security attribute “secure SCD import allowed”
is set to “no”.
Application note: Type 2 only.
FDP_ACF.1/Personalization SFP
FDP_ACF.1.1/
Personalization SFP
The TSF shall enforce the [Personalization SFP] to objects based on [General
attribute group]
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 Gemalto Public  Gemalto Private  Gemalto Restricted  Gemalto Confidential <code>  Gemalto Secret .
No disclosure to a third party without prior written consent of Gemalto
FDP_ACF.1.2/
Personalization SFP
The TSF shall enforce the following rules to determine if an operation among
controlled subjects and controlled objects is allowed:
User with the security attribute “role” set to “Administrator” is allowed to create
the RAD.
FDP_ACF.1.3/
Personalization SFP
The TSF shall explicitly authorize access of subjects to objects based on the
following additional rules [none].
FDP_ACF.1.4/
Personalization SFP
The TSF shall explicitly deny access of subjects to objects based on the rule:
[none].
FDP_ACF.1/Signature Creation SFP
FDP_ACF.1.1/
Signature-creation SFP
The TSF shall enforce the [Signature-creation SFP] to objects based on
[General attribute group] and [Signature-creation attribute group].
FDP_ACF.1.2/
Signature-creation SFP
The TSF shall enforce the following rules to determine if an operation among
controlled subjects and controlled objects is allowed:
User with the security attribute “role” set to “Signatory” is allowed to create
electronic signatures for DTBS sent by an authorized SCA with SCD by the
Signatory which security attribute “SCD operational” is set to “yes”.
FDP_ACF.1.3/
Signature-creation SFP
The TSF shall explicitly authorize access of subjects to objects based on the
following additional rules: [none].
FDP_ACF.1.4/
Signature-creation SFP
The TSF shall explicitly deny access of subjects to objects based on the rule:
User with the security attribute “role” set to “Signatory” is not allowed to create
electronic signatures for DTBS which is not sent by an authorized SCA with SCD
by the Signatory which security attribute “SCD operational” is set to “yes”.
User with the security attribute “role” set to “Signatory” is not allowed to create
electronic signatures for DTBS sent by an authorized SCA with SCD by the
Signatory which security attribute “SCD operational” is set to “no”.
6.1.3.3 FDP_ETC :Export to outside TSF control
FDP_ETC.1: Export of user data without security attributes
FDP_ETC.1/ SVD Transfer
FDP_ETC.1.1/ SVD
Transfer
The TSF shall enforce the [SVD Transfer SFP] when exporting user data,
controlled under the SFP(s), outside of the TSC.
FDP_ETC.1.2/ SVD
Transfer
The TSF shall export the user data without the user data’s associated security
attributes.
Application note:
FDP_ETC.1/SVD Transfer SFP will be required only, if the TOE holds the SVD and the SVD is exported to the
CGA for certification.
6.1.3.4 FDP_ITC Import From outside TSF control
FDP_ITC.1: Import of user data without security attributes
FDP_ITC.1/SCD
FDP_ITC.1.1/SCD The TSF shall enforce the [SCD Import SFP] when importing user data, controlled
under the SFP, from outside of the TSC.
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 Gemalto Public  Gemalto Private  Gemalto Restricted  Gemalto Confidential <code>  Gemalto Secret .
No disclosure to a third party without prior written consent of Gemalto
FDP_ITC.1.2/SCD The TSF shall ignore any security attributes associated with the user data when
imported from outside the TSC.
FDP_ITC.1.3/SCD The TSF shall enforce the following rules when importing user data controlled
under the SFP from outside the TSC: [SCD shall be sent by an Authorized
SSCD].
Application note:
A SSCD of Type 1 is authorised to send SCD to a SSCD of Type 2, if it is designated to generate the SCD for
this SSCD of Type 2 and to export the SCD for import into this SSCD of Type 2. Authorised SSCD of Type 1
are able to establish a trusted channel to the SSCD of Type 2 for SCD transfer as required by
FTP_ITC.1.3/SCD export.
Type 2 only.
Remark: Link with trusted channel SFP.
FDP_ITC.1/DTBS
FDP_ITC.1.1/DTBS The TSF shall enforce the [Signature-creation SFP] when importing user data,
controlled under the SFP, from outside of the TSC.
FDP_ITC.1.2/DTBS The TSF shall ignore any security attributes associated with the user data when
imported from outside the TSC.
FDP_ITC.1.3/DTBS The TSF shall enforce the following rules when importing user data controlled
under the SFP from outside the TSC: [DTBS-representation shall be sent by an
Authorized SCA].
Application note:
A SCA is authorised to send the DTBS-representation if it is actually used by the Signatory to create an
electronic signature and able to establish a trusted channel to the SSCD as required by FTP_ITC.1.3/SCA
DTBS.
Remark: Link with trusted channel and authenticate SFP.
6.1.3.5 FDP_RIP Residual information protection
FDP_RIP.1: Subset residual information protection
FDP_RIP.1.1 The TSF shall ensure that any previous information content of a resource is made
unavailable upon the [de-allocation of the resource from] the following objects: [SCD,
VAD, and RAD].
Remark: Link with SCD destruction SFP.
6.1.3.6 FDP_SDI Stored data integrity
FDP_SDI.2 Stored data integrity monitoring and action
FDP_SDI.2/Persistent
The following data persistently stored by TOE have the user data attribute “integrity checked persistent stored
data”
1. SCD
2. RAD
3. SVD (if persistently stored by TOE)
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No disclosure to a third party without prior written consent of Gemalto
FDP_SDI.2.1/
Persistent
The TSF shall monitor user data stored within the TSC for [integrity error] on
all objects, based on the following attributes: [integrity checked persistent
stored data].
FDP_SDI.2.2/
Persistent
Upon detection of a data integrity error, the TSF shall:
[ 1. prohibit the use of the altered data
2. inform the Signatory about integrity error.]
FDP_SDI.2/DTBS
The DTBS representation temporarily stored by TOE has the user data attribute “integrity checked stored data”
FDP_SDI.2.1/DTBS The TSF shall monitor user data stored within the TSC for [integrity error] on
all objects, based on the following attributes: [integrity checked stored data].
FDP_SDI.2.2/DTBS Upon detection of a data integrity error, the TSF shall:
[ 1. prohibit the use of the altered data
2. inform the Signatory about integrity error.]
Application note:
The DTBS-representation temporarily stored by TOE has the user data attribute "integrity checked stored
data".
6.1.3.7 FDP_UCT Inter-TSF user data confidentiality transfer protection
FDP_UCT.1 Basic data exchange confidentiality
FDP_UCT.1/Receiver
FDP_UCT.1.1/Receiver The TSF shall enforce the [SCD Import SFP] to be able to [receive] user data
in a manner protected from unauthorized disclosure.
Application note: Type 2 only.
6.1.3.8 FDP_UIT Inter-TSF user data integrity transfer protection
FDP_UIT.1: Data exchange integrity
FDP_UIT.1/SVD Transfer
FDP_UIT.1.1/ SVD
Transfer
The TSF shall enforce the [SVD Transfer SFP] to be able to [transmit] user
data in a manner protected from [modification and insertion] errors.
FDP_UIT.1.2/ SVD
Transfer
The TSF shall be able to determine on receipt of user data, whether
[modification and insertion] has occurred.
FDP_UIT.1/TOE DTBS
FDP_UIT.1.1/TOE DTBS The TSF shall enforce the [Signature-creation SFP] to be able to [receive]
user data in a manner protected from [modification, deletion and insertion]
errors.
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No disclosure to a third party without prior written consent of Gemalto
FDP_UIT.1.2/TOE DTBS The TSF shall be able to determine on receipt of user data, whether
[modification, deletion and insertion] has occurred.
Refinement: The mentioned user data is the DTBS-representation.
6.1.4 FIA: Identification and authentication
6.1.4.1 FIA_AFL Authentication failure
FIA_AFL.1 Authentication failure handling
FIA_AFL.1.1 The TSF shall detect when [3(for 5-digit RAD) or 5 (for 6-digit RAD)] unsuccessful
authentication attempts occur related to [consecutive failed authentication attempts].
FIA_AFL.1.2 When the defined number of unsuccessful authentication attempts has been [met] the TSF
shall [block RAD]
Refinement:
When the RAD is blocked, any attempt of authentication fails.
Remark: Link with Authenticate SFP.
6.1.4.2 FIA_ATD User attribute definition
FIA_ATD.1User attributes definition
FIA_ATD.1.1 The TSF shall maintain the following list of security attributes belonging to individual users
[RAD]
6.1.4.3 FIA_UAU User authentication
FIA_UAU.1 Timing of authentication
FIA_UAU.1.1 The TSF shall allow
1 [Identification of the user by means of TSF required by FIA_UID.1]
2 [Establishing a trusted channel between the TOE and a SSCD of type 1
by means of TSF required by FTP_ITC.1/SCD import]
3 [Establishing a trusted path between local user and the TOE by means of
TSF required by FTP_TRP.1/TOE]
4 [Establishing a trusted channel between the SCA and the TOE by means
of TSF required by FTP_ITC.1/DTBS import]
on behalf of the user to be performed before the user is authenticated.
FIA_UAU.1.2 The TSF shall require each user to be successfully authenticated before
allowing any other TSF-mediated actions on behalf of that user.
Application note:
“Local user” mentioned in component FIA_UAU.1.1 is the user using the trusted path provided between the
SGA in the TOE environment and the TOE as indicated by FTP_TRP.1/SCA and FTP_TRP.1/TOE.
Note: The TSF shall allow no Signature generation related action to be performed before user is authenticated.
That means that other actions, not specifically related to the Signature creation, may be performed before user
is authenticated.
Dependencies: FIA_UID.1 Timing of identification.
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No disclosure to a third party without prior written consent of Gemalto
6.1.4.4 FIA_UID User Identification
FIA_UID.1Timing of identification
FIA_UID.1.1 The TSF shall allow
1 [Establishing a trusted channel between the TOE and a SSCD of type 1
by means of TSF required by FTP_ITC.1/SCD import]
2 [Establishing a trusted path between local user and the TOE by means of
TSF required by FTP_TRP.1/TOE]
3 [Establishing a trusted channel between the SCA and the TOE by means
of TSF required by FTP_ITC.1/DTBS import]
on behalf of the user to be performed before the user is identified.
FIA_UID.1.2 The TSF shall require each user to be successfully identified before allowing any
other TSF-mediated actions on behalf of that user.
Note: The TSF shall allow no Signature generation related action to be performed before user is identified.
That means that other actions, not specifically related to the Signature creation, may be performed before user
is identified.
6.1.5 FMT: Security management
6.1.5.1 FMT_MOF Management of functions in TSF
FMT_MOF.1 Management of security functions behavior
FMT_MOF.1.1 The TSF shall restrict the ability to [enable] the [signature-creation function]
to [Signatory].
6.1.5.2 FMT_MSA Management of security attributes
FMT_MSA.1 Management of security attributes
FMT_MSA.1/Administrator
FMT_MSA.1.1/
Administrator
The TSF shall enforce the [Initialization SFP] and [SCD Import SFP] to restrict
the ability to [modify] the security attributes [SCD / SVD management and
secure SCD import allowed] to [Administrator].
Application note:
The SCD Import SFP enforcing comes from Type 2.
The Initialisation SFP enforcing comes from Type 3.
FMT_MSA.1/Signatory
FMT_MSA.1.1/
Signatory
The TSF shall enforce the [Signature-creation SFP] to restrict the ability to
[modify] the security attributes [SCD operational] to [Signatory].
FMT_MSA.2 Secure security attributes
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No disclosure to a third party without prior written consent of Gemalto
FMT_MSA.2.1 The TSF shall ensure that only secure values are accepted for [All security
attributes (see FDP_ACF.1)]
FMT_MSA.3 Static attribute initialization
FMT_MSA.3/Type 2
FMT_MSA.3.1/Type 2 The TSF shall enforce the [SCD Import SFP] and [Signature-creation SFP] to
provide [restrictive] default values for security attributes that are used to enforce
the SFP.
Refinement
The security attribute of the SCD “SCD operational” is set to “no” after import of the SCD.
FMT_MSA.3.2/Type 2 The TSF shall allow the [Administrator] to specify alternative initial values to
override the default values when an object or information is created.
FMT_MSA.3/Type 3
FMT_MSA.3.1/Type 3 The TSF shall enforce the [Initialization SFP] and [Signature-creation SFP] to
provide [restrictive] default values for security attributes that are used to
enforce the SFP.
Refinement
The security attribute of the SCD “SCD operational” is set to “no” after generation of the SCD.
FMT_MSA.3.2/Type 3 The TSF shall allow the [Administrator] to specify alternative initial values to
override the default values when an object or information is created.
6.1.5.3 FMT_MTD Management of TSF data
FMT_MTD.1 Management of TSF data
FMT_MTD.1.1 The TSF shall restrict the ability to [modify] the [RAD] to [Signatory].
Note: RAD being the PIN code, RAD and VAD are the same data.
6.1.5.4 FMT_SMF Specification of Management Functions
FMT_SMF.1 Specification of Management Functions
FMT_SMF.1.1 The TSF shall be capable of performing the following functions [Identification and
authentication management].
Additional SFR
6.1.5.5 FMT_SMR Security management roles
FMT_SMR.1 Security roles
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FMT_SMR.1.1 The TSF shall maintain the roles [Administrator] and [Signatory].
FMT_SMR.1.2 The TSF shall be able to associate users with roles.
6.1.6 FPT: Protection of the TSF
6.1.6.1 FPT_EMSEC TOE Emanation
FPT_EMSEC.1.1 TOE Emanation
FPT_EMSEC.1.1 The TOE shall not emit [Side channel current] in excess of [State of the art
limits] enabling access to [RAD and SCD].
Notes:
This SFR is an extension to [CCPART 2].
State of the art limits are the limits currently expected for IC meeting EAL4+ level of security.
FPT_EMSEC.1.2 The TSF shall ensure [all users] are unable to use the following interface
[external contacts] emanations to gain access to [RAD and SCD].
Notes:
This SFR is an extension to [CCPART 2].
State of the art limits are the limits currently expected for IC meeting EAL4+ level of security.
Remark: Link with Protection SFP.
6.1.6.2 FPT_FLS Failure secure
FPT_FLS.1 Failure with preservation of secure state
FPT_FLS.1.1 The TSF shall preserve a secure state when the following types of failures occur:
[power shortage, over and under voltage, over and under clock frequency, over
and under temperature, integrity problems, unexpected abortion of the execution
of the TSF due to external events.].
Remark: Link with Protection SFP.
6.1.6.3 FPT_PHP TSF physical Protection
FPT_PHP.1 Passive detection of physical attack
FPT_PHP.1.1 The TSF shall provide unambiguous detection of physical tampering that might
compromise the TSF.
FPT_PHP.1.2 The TSF shall provide the capability to determine whether physical tampering with the
TSF's devices or TSF's elements has occurred.
FPT_PHP.3 Resistance to physical attack
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FPT_PHP.3.1 The TSF shall resist [voltage, clock frequency and temperature out of bounds as
well as penetration attacks] to the [integrated circuit] by responding automatically
such that the TSP is not violated
Remark: Link with Protection SFP.
6.1.6.4 FPT_TST TSF self test
FPT_TST.1 TSF testing
FPT_TST.1.1
The TSF shall run a suite of self-tests [during initial start-up] to demonstrate the
correct operation of the TSF.
FPT_TST.1.2 The TSF shall provide authorized users with the capability to verify the integrity of TSF
data.
FPT_TST.1.3 The TSF shall provide authorized users with the capability to verify the integrity of stored
TSF executable code.
Remark: Link with Protection SFP.
6.1.7 FTP: Trusted Path / Channel
6.1.7.1 FTP_ITC Inter-TSF trusted channel
FTP_ITC.1 Inter-TSF trusted Channel
FTP_ITC.1/SCD import
FTP_ITC.1.1/SCD import The TSF shall provide a communication channel between itself and another
trusted IT product that is logically distinct from other communication channels
and provides assured identification of its end points and protection of the
channel data from modification or disclosure.
FTP_ITC.1.2/SCD import The TSF shall permit [another trusted IT product] to initiate communication
via the trusted channel.
FTP_ITC.1.3/SCD import The TSF shall initiate communication via the trusted channel for [SCD import]
Refinement: The mentioned remote trusted IT product is a SSCD of type 1.
Application note:
The SCD Import must be protected in Integrity. This protection must be ensured by crypto mechanisms in the
TOE. No “Trusted Environment” can ensure this integrity.
Type 2 only.
Remark: Link with SCD import SFP.
FTP_ITC.1/SVD Transfer
FTP_ITC.1.1/SVD
Transfer
The TSF shall provide a communication channel between itself and another
trusted IT product that is logically distinct from other communication channels
and provides assured identification of its end points and protection of the
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channel data from modification or disclosure.
FTP_ITC.1.2/SVD
Transfer
The TSF shall permit [another trusted IT product] to initiate communication
via the trusted channel.
FTP_ITC.1.3/SVD
Transfer
The TSF shall initiate communication via the trusted channel for [SVD Transfer]
Refinement: The mentioned remote trusted IT product is a CGA or the SCA application that will transmit the
SVD to the CGA.
Application note:
The SVD Transfer must be protected in Integrity. This protection can be ensured by crypto mechanisms in the
TOE. It can also be ensured by a “Trusted Environment”. At personalization time, the Issuer will be able to
assess if the usage environment will be a “Trusted Environment”.
Remark: Link with SVD transfer SFP.
FTP_ITC.1/ DTBS import
FTP_ITC.1.1/DTBS import The TSF shall provide a communication channel between itself and another
trusted IT product that is logically distinct from other communication channels
and provides assured identification of its end points and protection of the
channel data from modification or disclosure.
FTP_ITC.1.2/DTBS import The TSF shall permit [another trusted IT product] to initiate communication
via the trusted channel.
FTP_ITC.1.3/DTBS import The TSF shall initiate communication via the trusted channel for [signing
DTBS-representation]
Refinement: The mentioned remote trusted IT product is a SCA.
Application note:
The DTBS Import must be protected in Integrity. This protection can be ensured by crypto mechanisms in the
TOE. It can also be ensured by a “Trusted Environment”. At personalization time, the Issuer will be able to
assess if the usage environment will be a “Trusted Environment”.
Remark: Link with Signature creation SFP.
6.1.7.2 FTP_TRP Trusted path
FTP_TRP.1 Trusted path
FTP_TRP.1.1 The TSF shall provide a communication path between itself and [local] users that is
logically distinct from other communication paths and provides assured identification of
its end points and protection of the communicated data from [modification,
disclosure].
FTP_TRP.1.2 The TSF shall permit [local users] to initiate communication via the trusted path.
FTP_TRP.1.3 The TSF shall require the use of the trusted path for [initial user authentication][no
other service].
Application note:
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The RAD/VAD Import must be protected in Integrity and confidentiality. This protection can be ensured by
crypto mechanisms in the TOE. It can also be ensured by a “Trusted Environment”. At personalization time, the
Issuer will be able to assess if the usage environment will be a “Trusted Environment”.
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6.2 SECURITY ASSURANCE REQUIREMENTS
The TOE security assurance requirements define the assurance requirements for the TOE using only
assurance components drawn from [CCPART3].
The assurance level is EAL4 augmented on:
• ALC_DVS.2: Sufficiency of security measures.
• AVA_VAN.5: Advanced methodical vulnerability analysis
6.2.1 TOE security assurance requirements list
Table below shows equivalence between SAR in CC V2.3 and SAR CC V3.1.
CC V3.1 will be followed on this part.
Assurance
Family
CC2.x
Assurance
Family
CC3.1
Assurance
class
ACM_AUT --
ACM_CAP ALC_CMC
Configuration
Management
ACM_SCP ALC_CMS
ADO_DEL ALC_DEL
partially
AGD_PRE [1.1C]
Delivery and operation ADO_IGS installation:
AGD_PRE [1.2C]
start-up:
part of ADV_ARC
[1.3C]
ADV_LLD
ADV_TDS
partially
ADV_ARC [1.2C,
1.4C, 1.5C]
ADV_FSP ADV_FSP
ADV_IMP ADV_IMP
Development
ADV_HLD ADV_TDS
AGD_USR AGD_OPE
Guidance documents
AGD_ADM AGD_OPE
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Assurance
Family
CC2.x
Assurance
Family
CC3.1
Assurance
class
--
(ACM_CAP)
ALC_CMC
--
(ACM_SCP)
ALC_CMS
--
(ADO_DEL)
ALC_DEL
ALC_DVS ALC_DVS
ALC_LCD ALC_LCD
Life-cycle support
ALC_TAT ALC_TAT
Security Target evaluation ASE ASE
ATE_COV ATE_COV
ATE_DPT ATE_DPT
ATE_FUN ATE_FUN
Tests
ATE_IND ATE_IND
AVA_CCA AVA_VAN
AVA_VLA AVA_VAN
AVA_SOF AVA_VAN
Vulnerability assessment
AVA_MSU AGD_OPE
[1.5C – 1.8C]
AGD_PRE.1.2C
(WU AGD_PRE.1-
4) AGD_PRE.1.2E
Table 6. SAR CC V2.3 versus CC V3.1
Identification Description
ADV Development
ADV_ARC.1 Security architecture description
ADV_FSP.4 Complete functional specification
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ADV_IMP.1 Implementation representation of the TSF
ADV_TDS.3 Basic modular design
AGD Guidance documents
AGD_OPE.1 Operational user guidance
AGD_PRE.1 Preparative procedures
ALC Life cycle support
ALC_CMC.4 Production support, acceptance procedures and automation
ALC_ CMS.4 Problem tracking CM coverage
ALC_DEL.1 Delivery procedures
ALC_DVS.2 Sufficiency of security measures
ALC_LCD.1 Developer defined life-cycle model
ALC_TAT.1 Well-defined development tools
ATE Tests
ATE_COV.2 Analysis of coverage
ATE_DPT.1 Testing : Testing: basic design
ATE_FUN.1 Functional testing
ATE_IND.2 Independent testing – sample
AVA Vulnerability assessment
AVA_VAN.5 Methodical vulnerability analysis,
Table 7. TOE security assurance requirements list
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7 TOE SUMMARY SPECIFICATION
The security functions provided by the IC are described in [IC-ST]. The TOE Security Functionalities are
described below.
7.1 TOE SECURITY FUNCTIONALITIES PROVIDED BY PLATFORM
7.1.1 TSF_CARD_EMANATION: Emanation protection
This security functionality protects the electronic signature application data RAD and SCD against snooping.
The security functionality ensures that:
• The TOE shall not emit electromagnetic radiation in excess of unintelligible emission enabling
access to RAD and SCD.
• The TOE shall ensure that the attacker S.OFFCARD is not able to use I/O, VCC or Ground interface
to gain access to RAD and SCD.
This security function is supported by the IC security function F.LOG: Logical Protection (see [IC-ST]).
7.1.2 TSF_CARD_PROTECT: Card operation protection
This security functionality ensures the protection of the TSF and supports the following operations.
• Analyze potential violation on the card life-cycle inconsistency, the PIN and keys integrity error, the illegal
access to Java objects, and the unavailability of resources.
• Take action upon violation detection: reset the card, block the action, terminate or mute the card.
• Check start-up security conditions: the consistency of life-cycle, the integrity of specific data area.
• Check operating conditions periodically by listening the IC sensors.
• Resist to physical attacks (such as out-of-bound voltage, clock frequency and temperature, etc)
In case of error detections this function returns an error or an exception and takes appropriate shield action. If
during the TSF execution an unexpected error or an abortion occurs, a secure state will be preserved by
resetting security attributes to secure values and if necessary recover the persistently stored data to a secure
consistent state.
This security function ensures the atomicity of Java objects update in EEPROM:
• The content of the data that are modified within a transaction is copied in the transaction dedicated
EEPROM area. The TSF manages an optimistic backup: the optimistic backup mechanism includes a
backup of the previous data value at first data modification, and previous value restoring at abort.
• Commit operation closes the transaction, and de-activates the dedicated transaction area.
• Rollback operation restores the original values of the objects (modified during the transaction) and de-
activates the dedicated transaction area.
• The security function ensures that the EEPROM containing sensitive data is in a consistent state whatever
the time when EEPROM programming sequence stops, either during copying, invalidating, restoring data
to or from the backup dedicated EEPROM area or updating sensitive data in EEPROM.
This TSF is supported by the IC security function F.PHY: Protection against Physical Manipulation (see [IC-
ST]).
7.2 TOE SECURITY FUNCTIONALITIES PROVIDED BY IAS ECC APPLET
7.2.1 TSF_ AUTHENTICATION: Authentication management
This security functionality manages the authentication mechanisms such as:
− Authentication operations for role management (i.e. PIN verification)
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− Authentication operations for secure channel management (i.e. mutual authentication with
symmetric and asymmetric schemes).
This security function:
• Manages authentication failure: when the 3 (for 5-digit RAD) or 5 (for 6-digit RAD)
unsuccessful authentication attempts has been met or surpassed, the TSF shall block D.RAD.
• Manage the asset D.RAD.
• Handles the authentications (for opening a secure channel) during the personalization and
application phases.
This security functionality allows the following operations to be performed before the user is authenticated:
• Identification of the user
• Establishing a trusted path between local user and the TOE
• Establishing a trusted channel between the SCA and the TOE for D.DTBS import
• Establishing a trusted channel between the TOE and the SSCD Type 1 for D.SCD import
7.2.2 TSF_CRYPTO: Cryptography management
This security functionality manages the cryptographic operations of the electronic signature application:
• Key generation and correspondence verification (for RSA keypairs)
• Key destruction
• Perform cryptographic operations
Cryptographic algorithms TDES, RSA and RNG and provided by the platform and ensures that D.SCD
information is made unavailable after use (key destruction).
• TDES algorithm only support 112-bit key
• RSA algorithm supports 1024, 1536, 2048 bits keys. The RSA algorithm is SW and does not use the IC
cryptographic library, only the IC cryptographic co-processor is used. The platform supports CRT RSA.
• Random generator uses the certified Hardware Random Generator that fulfils the requirements of AIS31
(see [IC-ST]).
• SHA-1 and SHA-256 algorithms
This security function controls all the operations relative to the card keys management (provided also by the
platform)
• Key generation: The TOE provides the following:
RSA key generation manages 1024, 1536, 2048 bits long keys. The RSA key generation is SW and does
not use the IC cryptographic library.
The TDES key generation (for session keys) uses the random generator.
• Key destruction: the TOE provides a specified cryptographic key destruction method that makes Key
unavailable.
This security functionality ensures the confidentiality of keys during manipulation and ensures the de-allocation
of memory after use.
This security functionality is supported by the IC security function F.RNG (Random Generator), F.HW_DES
(Triple-DES Co-processor), (see [IC-ST]).
7.2.3 TSF_INTEGRITY: Integrity monitoring
This security functionality monitors the integrity of sensitive user data and the integrity of the DTBS. The
integrity of persistently stored data such as D.SCD, D.RAD and D.SVD is monitored using the platform
features.
In case of integrity error this TSF will
• Prohibit the use of the altered data, and
• Inform the S.Signatory about integrity error.
This TSF also monitors the integrity of the access conditions of created data objects and also ensures that no
residual information is available after a PIN update or clearance.
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7.2.4 TSF_MANAGEMENT: operation management and access control
This security functionality provides application operation management and access control.
Operation management
This security functionality manages the electronic signature application during its initialization and operation.
This SF manages the security environment of the application and:
• Maintains the roles S.Signatory, S.Admin.
• Controls if the authentication required for a specific operation has been performed with success.
• Manages restriction to security function access and to security attribute modification.
• Ensures that only secure values are accepted for security attributes.
This security functionality restricts the ability to perform the function Signature-creation SFP to S.Signatory.
This security functionality ensures that only S.Admin is authorized to
• Modify Initialization SFP and Signature-creation SFP attributes
• Specify alternative default values
Access control
This security functionality provides the electronic signature application with access control and ensures that the
following operations are executed by authorized roles:
• Export of D.SVD by S.User
• Import of D.SCD by S.User
• Generation of D.SCD/D.SVD pair by S.User
• Creation of D.RAD by S.Admin
• Signing of D.DTBS-representation by S.Signatory
This security functionality provides access control to data objects.
This security functionality enforces the security policy on the import and the export of user data on:
• SVD Transfer SFP: D.SVD shall be sent to an authenticated CGA.
• Signature-creation SFP: D.DTBS shall be sent by an authenticated SCA.
7.2.5 TSF_SECURE_MESSAGING: secure messaging management
This security functionality ensures the integrity and the confidentiality of exchanged user data.
This security functionality ensures that the TSF is able to
• Receive D.SCD with protection from unauthorized disclosure.
• Transmit D.SVD with protection from modification and insertion errors.
• Receive D.DTBS with protection from modification, deletion and insertion errors.
• Determine on received user data whether modification, deletion or insertion has occurred.
This security functionality manages four modes of secure channel during the personalization phase
• No secure messaging
• Integrity mode
• Confidentiality mode
• Integrity and confidentiality mode
During the application personalization phase secure messaging provided by the platform is used. This ensures
the integrity and/or the confidentiality of command/message transmission in a secure channel. The integrity is
achieved by adding a message authentication code to the message. The confidentiality is achieved by APDU
message data field encryption. These features are used in accordance with the security mode applied to the
secure channel.