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Security Target
BSI-DSZ-CC-0196
Version 1.0
August 8th, 2002
Evaluation of the
Philips P8WE6017V1J
Secure 8-bit Smart Card Controller
Developed and provided by
Philips Semiconductors, Business Unit Identification
According to the
Common Criteria for Information Technology
Evaluation (CC) at Level EAL5 augmented
by
Philips Semiconductors GmbH
Stresemannallee 101
22505 Hamburg
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Document Information
Document History
Version Date Changes Remarks
Version 1.0 August 8th
, 2002 Draft compliant to PP/9806
Latest version is: Version 1.0 (August 8th, 2002)
Document Invariants
Name Value (to be edited) Test Output (to copy)
file name and length Automatically st_6017V1J_9806_v1_0.doc
(426496 Byte)
latest version Version 1.0 Version 1.0
date of this version August 8th
, 2002 August 8th
, 2002
classification Security Document – Strictly
Confidential
Security Document – Strictly Confi-
dential
product (short) Philips P8WE6017V1J smart card
controller
Philips P8WE6017V1J smart card
controller
product (long) Philips P8WE6017V1J
Secure 8-bit Smart Card
Controller
Philips P8WE6017V1J
Secure 8-bit Smart Card Controller
developer (long) Philips Semiconductors, Business
Unit Identification
Philips Semiconductors, Business
Unit Identification
developer (short) Philips Philips
registration number BSI-DSZ-CC-0196 BSI-DSZ-CC-0196
list of authors Hans-Gerd Albertsen Hans-Gerd Albertsen
certific. body (short) BSI BSI
certific. body (long) Bundesamt für Sicherheit in der
Informationstechnik (BSI)
Bundesamt für Sicherheit in der In-
formationstechnik (BSI)
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Table of Contents
1 ST Introduction 5
1.1 ST Identification 5
1.2 ST Overview 5
1.3 CC Conformance 6
2 TOE Description 8
2.1 TOE Definition 8
2.2 Further Definitions and Explanations 13
3 Security Environment 14
3.1 Definition of Subjects, Objects and Access Modes 14
3.2 Assets 18
3.3 Assumptions 18
3.4 Threats 18
3.5 Organisational Security Policies 18
4 Security Objectives 19
4.1 Security Objectives for the TOE 19
4.2 Security Objectives for the Environment 21
5 IT Security Requirements 22
5.1 TOE Security Requirements 22
5.2 Security Requirements for the Environment 35
6 TOE Summary Specification 37
6.1 TOE Security Functions 37
6.2 Assurance measures 39
7 PP Claims 42
8 Rationale 43
8.1 Security Objectives Rationale 43
8.2 Security Requirements Rationale 44
8.3 TOE Summary Specification Rationale 47
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8.4 PP Claims Rationale 48
9 Annexes 49
9.1 Definition of specific IT security functional requirements 49
9.2 Abbreviations 50
9.3 Bibliography 51
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1 ST Introduction
The chapter ST Introduction is divided into the following sections:
ST Identification
ST Overview
CC Conformance
1.1 ST Identification
This Security Target (st_6017V1J_9806_v1_0.doc, Version 1.0, August 8th
, 2002) refers to the
"Philips P8WE6017V1J Secure 8-bit Smart Card Controller" (TOE) for a Common Criteria
evaluation.
1.2 ST Overview
The TOE is the hardware of the microcontroller chip Philips P8WE6017V1J smart card con-
troller composed of a processing unit, security components, I/O ports, cryptographic co-processor
and volatile and non-volatile memories produced by Philips. The Philips P8WE6017V1J smart
card controller includes IC Dedicated Software for test purposes stored in the Test-ROM of the
microcontroller. The TOE includes the documentation, which consists of a Data Sheet and an
additional Guidance Document. The documentation contains a description of the architecture,
the secure configuration of the chip by the application software and the instruction set.
The security features of the Philips P8WE6017V1J smart card controller are mostly independent
from the application software and support the usage for a wide range of security applications
within the information technology. The TOE is embedded in a micro-module or another sealed
package. The micro-modules are embedded into a credit card sized plastic card.
The non-volatile EEPROM makes the TOE ideal for applications requiring non-volatile data
storage, including smart cards and portable data banks. Security functions protect data in the on-
chip ROM, EEPROM and RAM. In particular when being used in the banking and finance
market or in electronic commerce applications the smart card must provide security. Hence the
TOE shall
- maintain the integrity and the confidentiality of data stored in the memory of the TOE
and
- maintain the integrity, the correct operation and the confidentiality of security functions
(security mechanisms and associated functions) provided by the TOE.
This is ensured by the construction of the TOE and by security functions provided by the TOE.
Usually the smart card is assigned to a single individual only but may store and process secrets of
the system too. So, the TOE must meet security requirements to be applied to security modules.
The "Philips P8WE6017V1J Secure 8-bit Smart Card Controller" (TOE) mainly provides a
hardware platform for a smart card with
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- functions to calculate the Data Encryption Algorithm (DEA) resistant to Differential
Power Analysis (DPA) attacks,
- a random number generator and
- mode control regarding a test mode and a user mode.
In addition several security features independently implemented in hardware or controlled by
software will be provided to ensure proper operations and integrity and confidentiality of stored
data. This includes for example measures for memory protection and sensors to allow operations
only under specified conditions.
Regarding the life cycle of the smartcard the development and the production phase of the IC
with its dedicated software as described for the Target of Evaluation (TOE) is part of the evalua-
tion. This is based on
- the description of the security environment of the TOE including the assets to be pro-
tected and the threats to be countered by the TOE and by the operational environment
during the development, production and user phases,
- the description of the security objectives for the TOE and for its environment in terms of
integrity and confidentiality of application data and programs, protection of the TOE and
associated documentation during the development and production phases and
- the specification of the security requirements which includes the TOE security functional
requirements and the TOE security assurance requirements.
1.3 CC Conformance
The Evaluation is based upon
- Common Criteria for Information Technology Security Evaluation, Part 1: Introduction
and General Model; Version 2.1, August 1999, [1]
- Common Criteria for Information Technology Security Evaluation, Part 2: Security
Functional Requirements; Version 2.1, August 1999, [2]
- Common Criteria for Information Technology Security Evaluation, Part 3: Security As-
surance Requirements; Version 2.1, August 1999, [3]
For the evaluation the following methodology will be used
- Common Methodology for Information Technology Security Evaluation CEM-99/045
Part 2: Evaluation Methodology, Version 1.0, August 1999, [4]
The chosen level of assurance is
EAL 5 augmented.
EAL 5 augmented.
EAL 5 augmented.
EAL 5 augmented. The minimum strength level for the TOE security functions is SOF-high
(Strength of Functions High
Strength of Functions High
Strength of Functions High
Strength of Functions High).
This security Target claims the following CC conformances:
- Part 2 extended
Part 2 extended
Part 2 extended
Part 2 extended, Part 3 augmented
Part 3 augmented
Part 3 augmented
Part 3 augmented.
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- The Security Target is conformant to the PP/9806
conformant to the PP/9806
conformant to the PP/9806
conformant to the PP/9806 Version 2.0 (see section 7 for details).
The level of evaluation and the functionality of the TOE are chosen in order to allow the confir-
mation that the TOE is suitable for use within devices compliant with the German Digital Sig-
nature Law.
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2 TOE Description
This chapter is divided into the following sections: “TOE Definition” and “Further Definitions
and Explanations”. TOE Definition has the sub-sections “Hardware Description”, “Software
Description”, “Documentation”, “Interface of the TOE”, “Life Cycle and Delivery of the TOE”,
“TOE Intended Usage”, “TOE User Environment” as well as “General IT features of the TOE”.
2.1 TOE Definition
The Target of Evaluation (TOE) is the smartcard integrated circuit depicted in figure 1 as block
diagram. The TOE named Philips P8WE6017V1J smart card controller is manufactured in an
advanced CMOS process. The TOE includes IC Designer/Manufacturer proprietary IC Dedi-
cated Software in an 6kByte part of the ROM. This software (also known as IC firmware) is used
for testing purposes during production only and does not provide additional services. All other
software is called Smartcard Embedded Software and is not part of the TOE.
Figure
Figure
Figure
Figure 1
1
1
1 Block Diagram of the
Block Diagram of the
Block Diagram of the
Block Diagram of the Philips P8WE6017V1J smart card controller
Philips P8WE6017V1J smart card controller
Philips P8WE6017V1J smart card controller
Philips P8WE6017V1J smart card controller
The device is developed for most high-end safeguarded applications, and is designed for embed-
ding into chip cards according to ISO 7816 [8]. The secret data shall be used as input for the
calculation of authentication data, the calculation of signatures and the encryption of data and
keys. Each security measure is designed to act as an integral part of the complete system in order
to strengthen the design as a whole. The security measures can be divided into hardware con-
trolled security measures that do not allow for software guided exceptions and security measures
that shall be controlled by software.
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The following table lists the TOE components for the Philips P8WE6017V1J smart card con-
troller.
Type Name Release Date Form of delivery
Hardware Philips P8WE6017V1J Se-
cure 8-bit Smart Card Controller
V1J 13.05.2002
(GDS2 File 1
)
Wafer (dice include
reference C009J or
P009J)
Software Test ROM Software (the IC dedi-
cated software)
xk033b 17.01.2002 Test ROM on the
chip
Document Guidance, Delivery and Operation
Manual
printed document
Document Data Sheet, P8WE6017 Secure
8-bit Smart Card Controller
3.3 July 5th
, 2002 printed document
Table
Table
Table
Table 1
1
1
1: Components of the TOE
: Components of the TOE
: Components of the TOE
: Components of the TOE
Note that the first character of the die reference for the Philips P8WE6017V1J smart card con-
troller depends on the production site of the wafer.
2.1.1 Hardware Description
The CPU of the Philips P8WE6017V1J smart card controller is a derivative of the 80C51 family
and has the same instruction set. The instruction set contains 255 different instructions, each
instruction has a length of one byte which can be followed by parameters consisting of one or two
additional bytes. The on-chip hardware is controlled by software via Special Function Registers.
These registers are correlated to the activities of the CPU, Interrupt, I/O, EEPROM, Timers,
UART and the co-processor. The communication with the TOE can be performed through a
serial interface I/O according to ISO standard 7816-3 [9]. Two 16-bit timers and six vectorized
interrupts provide further functionality for I/O, timers and EEPROM.
The device includes ROM (48 kByte User-ROM + 6 kByte Test-ROM), RAM (1280 Byte) and
EEPROM (16 kByte) memory. The EEPROM can be accessed as data memory as well as pro-
gram memory. The Triple-DES co-processor supports single DES and Triple-DES operations,
but only Triple-DES will be used in this evaluation. The random number generator provides true
random numbers without pseudo random calculation.
The Philips P8WE6017V1J smart card controller operates with a single 3V or 5V nominal power
supply at a nominal maximum external clock frequency of 8 MHz. The controller provides an
internal clock to perform security algorithms. The controller provides two power saving modes
1
Note that since the TOE will be produced in two different wafer fabs, two different files are needed because
Philips wants to be able to identify the origin. Both files were prepared at the same date and can be distinguished
by the file name.
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with reduced activity: the IDLE Mode and the SLEEP Mode, which includes the CLOCK STOP
Mode.
The TOE protects the secret data stored in and operated by the TOE against physical tampering.
Within the composition of this TOE, the operating system, and the smart card application the
security functionality is only partly provided by the TOE and causes dependencies between the
TOE security functions and the functions provided by the operating system or the smart card
application on top.
2.1.2 Software Description
The smart card operating system and the application are developed by the customer and called
Smartcard Embedded Software in the following. The Smartcard Embedded Software is stored in
the User-ROM and/or in the EEPROM and is not a part of the TOE. The application software
depends on the usage of the smartcard.
The code in the Test-ROM of the TOE is used by the TOE Manufacturer of the smart card to
check the chip function. This IC Dedicated Software is disabled before the operational use of the
smart card. The IC Dedicated Software (called firmware in the following) is developed by Philips
and embedded in the Test-ROM. The firmware includes the test operating system, test routines
for the various blocks of the circuitry, control flags for the status of the EEPROM’s security area
and shutdown functions to ensure that security relevant test operations cannot be executed ille-
gally after phase 3.
2.1.3 Documentation
The Data Sheet [10] of the Philips P8WE6017V1J smart card controller is also part of the TOE.
It contains a functional description needed to develop software, guidelines for the use of security
features and the instruction set of the TOE. Additional application notes describe aspects of the
program interface and the use of programming techniques to improve the security. The provided
documentation can be used by the application software developer to develop the Smartcard Em-
bedded Software.
2.1.4 Interface of the TOE
In the user mode the electrical interface of the TOE are the pads to connect the lines power sup-
ply, reset input, clock input, ground and I/O1.
The software interface of the TOE depends on the operation mode of the TOE:
- In the user mode the software interface is the set of instructions, the bits in the special
function registers that are related to the user mode and described in the data sheet as well
as the address map of the CPU including memories.
Note: The interface of the TOE after phase 3 is based on the embedded software devel-
oped by the application software developer.
- In the Test Mode the interface is the set of test functions based on the test operating sys-
tem in the Test-ROM and provided at the electrical interface.
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The chip surface can be seen as an interface of the TOE, too. This is in the case of an attack
where the attacker manipulates the chip surface.
Note that the phase in which the TOE is switched to the user mode depends on the form of de-
livery requested by the customer. If the TOE is delivered as wafer it is switched to the user mode
at the end of phase 3. If the TOE is delivered as module it is switched to the user mode at the end
of phase 4. In all cases the TOE is switched to the user mode before Philips delivers the TOE to
the customer.
2.1.5 Life Cycle and Delivery of the TOE
This Security Target uses the same life-cycle model as described in the Protection Profile
PP/9806, section 2.2. The life cycle consists of the following phases:
Phase 1: Smartcard embedded software development
Phase 2: IC Development
Phase 3: IC manufacturing and testing
Phase 4: IC packing and testing
Phase 5: Smartcard product and finishing process
Phase 6: Smartcard personalisation
Phase 7: Smartcard end usage
For a detailed description of the phases please refer to the Protection Profile.
For the usage phase the Philips P8WE6017V1J smart card controller chip will be implemented in
a credit card sized plastic card (micro-module embedded into the plastic card) or another sealed
package. The chip provides a hardware computing platform to run smart card applications exe-
cuted by a smart card operating system. Smart card applications will be used to store secret data
and calculate cryptographic functions.
The module and card embedding of the TOE provide external security mechanisms because they
make it harder for an attacker to access parts of the TOE for physical manipulation.
The TOE is able to control two different logical phases. After production the chip is in the Test
Test
Test
Test
Mode
Mode
Mode
Mode that means under the control of the test software. At the end of the production test the
chip will be switched into the User Mode
User Mode
User Mode
User Mode so that the chip is under the control of the application
software.
2.1.6 TOE Intended Usage
Regarding to phase 7, the combination of the smartcard hardware and the application software is
used by the end-user. The method of use of the product in this phase depends on the application.
During the other phases of the product construction and product usage there are several admin-
istrator- and user-functions.
Phase 1: The smartcard embedded software developer develops software for the smartcard,
including a smartcard operating system and/or application specific software parts.
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By using the software interface of the TOE (in user mode) as defined in section
2.1.4 he/she is the user of the smartcard hardware with the hardware features.
Phase 2: The IC designer is responsible for the design of the chip that is developed within
this phase. In parallel the IC designer develops the IC Dedicated Software for the
production test of the chip that is included in the Test-ROM. Therefore the IC
designer takes the role of the administrator during this phase.
Phase 3: The function of the administrator is split into two parts: The IC manufacturer is
responsible for the IC production itself. Regarding to the production test after the
manufacturing process the test engineer is the administrator.
Note: The definition of the user roles regarding the TOE for the phases 4 to 7 is provided here
as additional information and is not in the scope of the evaluation. However the operation manu-
als address some of the user roles defined for phase 1 and the following phases.
Phase 4: the IC packaging manufacturer (administrator),
the smartcard embedded software developer (user),
the system integrators such as the terminal software developer (user).
Phase 5: the smartcard product manufacturer (administrator),
the smartcard embedded software developer (user),
the system integrators such as the terminal software developer (user).
Phase 6: the personaliser (administrator),
the smartcard issuer (administrator),
the smartcard embedded software developer (user),
the system integrators such as the terminal software developer (user).
Phase 7: the smartcard issuer (administrator),
the smartcard end-user (user),
the smartcard embedded software developer (user),
the system integrators such as the terminal software developer (user).
The smartcard embedded software developer and the system integrators such as the terminal
software developer are listed in Phases 4-7 because they may use samples of the TOE in these
phases for their testing purposes. It is not intended that they are able to change the behaviour of
the smartcard in another way than an user.
The IC manufacturer and the smartcard product manufacturer may receive ICs from different
phases for analysis purpose, if problems should occur during the smartcard usage.
2.1.7 TOE User Environment
The TOE user environment is the environment of phases 4 to 7. At phases 4, 5 and 6, the TOE
user environment must be a controlled environment.
In the end-user environment (phase 7) Smartcard ICs are used in a wide range of applications to
assure authorised conditional access. Examples of such are Pay-TV, Banking Cards, Portable
communication SIM cards, Health cards, Transportation cards. The end-user environment
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therefore covers a wide spectrum of very different functions, thus making it difficult to avoid and
monitor any abuse of the TOE.
Phases 4 to 7 of the smart card life cycle are not part of the TOE construction process in the sense
of this Security Target. Information about those phases are just included to describe how the
TOE is used after its construction. Nevertheless the security features of the Smartcard IC hard-
ware that are independent of the software are active from the end of phase 3 and cannot be dis-
abled by the application software in the phases 4 to 7.
2.1.8 General IT features of the TOE
The TOE IT functionality consist of:
- tamper resistant data storage
- basic cryptographic functions (Triple-DES co-processor)
- physical random number generator
- data communication
2.2 Further Definitions and Explanations
Since the Security Target claims conformance to the PP “Protection Profile, Smartcard Integrated
Circuit; Common Criteria for Information Technology Security Evaluation; Version 2.0, Sep-
tember 1998, registered at the French Certification Body under number PP/9806”, the concepts
are used in the same sense. For the definition of terms refer to the Protection Profile [6]. This
chapter does not need any supplement in the Security Target.
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3 Security Environment
The chapter Security Environment is divided into the following sections: “Definition of Subjects,
Objects and Access Modes”, “Assets”, “Assumptions”, “Threats” and “Organisational Security
Policies”.
3.1 Definition of Subjects, Objects and Access Modes
In this section definitions are given for:
- the subjects, which are able to use the TOE,
- the objects that are protected by the TOE,
- the Access Modes and Methods, which describe, how the subjects can act on the objects
based on the technical opportunities.
Note, that in order to make the analysis of potential attack scenarios possible, even access meth-
ods are defined and discussed, which are effectively prevented by the TOE.
These definitions describe the TSF Scope of Control (TSC) and are used in later chapters (e. g. to
define operations for some of the Security Functional Requirements).
3.1.1 Subjects
Subjects relevant for considering the security of the TOE are:
(S1) the administrator
The test engineer of the IC manufacturer using the Test Mode ROM to test the correct function
of the IC according to the manufacturing specification. Regarding to the assumptions of the envi-
ronment during the manufacturing process no user is considered as attacker. Nevertheless the
tamper resistance measures are already active. This administrator is defined only for phase 3, after
this phase the administrator is not able to act as administrator.
(S2) the end-user
This definition includes all subjects that can get access to the TOE within phase 4 to 7 when the
TOE is switched in the user mode. This might be the legal owner of the smart card or another
person who succeeds in getting access to the smart card with the final TOE. It also includes the
users that are defined as administrator for the different personalisation steps of phases 4 to 7.
These persons may perform direct attacks on the smartcard containing the TOE to access the
objects or processed data circumventing the access provided by the application software.
(S3) the test software
This means the IC dedicated software, when it is executed by the TOEs CPU and therefore able
to act as a subject. This is only possible within phase 3. The test software is developed by the IC
manufacturer and implemented in the TOE's Test-ROM as object O1.
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(S4) the application software
This means the software built by the application developer and implemented in the TOE's User-
ROM and E2PROM as object O2. The application software can be used at first when the chip is
switched to the user mode.
3.1.2 Objects
This section defines the objects and access methods relevant for considering the usage of the TOE
based on the technical opportunities of the subjects.
(O1) Test software while being stored in the test area read-only memory (Test-ROM). This
object may be (i) executed (i. e. A5 starting S3) or (ii) might be manipulated A4.
(O2) Application software while being stored in the user area of the read-only memory (User-
ROM) and the electrically erasable PROM (E2PROM). This object may be (i) executed
(i. e. A5 starting the subject S4), (ii) written A7 by the test software S3 or the application
software S4 itself, or (iii) might be manipulated A4.
Note that the test software S3 and the application software S4 can modify (write A7) only
the E2PROM part of the application software.
(O3) Application data while being stored in the electrically erasable PROM (E2PROM) or the
random-access memory (RAM) of the TOE. This object may be (i) read A6 by the test
software S32
and by the application software S4, (ii) written A7 by the test software S3
and by the application software S4, or (iii) might be manipulated A4. Note that the
application data are described by O3 during storage and by O6 during processing.
(O4) Random numbers generated by the random number generator (RNG) of the TOE. This
object may (i) be read A6 by the test software S3 and the application software S4, and (ii)
might be measured A1, affected A2, influenced A3 or manipulated A4.
(O5) Configuration data while being stored in the one time programmable memory (OTP) of
the TOE. This object may be (i) read A6 by the test software S3 and the application soft-
ware S4, (ii) set A8 by the test software S3 and the application software S4 and (iii) might
be manipulated A4.
Note that due to the TOE design the OTP may be modified by means of the software
running on the TOE only in one direction. This is described by the access method set A8.
(O6) Information of the data O3 and O4 while being processed by the CPU and the DES co-
processor of the TOE. This object may be (i) processed A9 by the test software S3 or by
the application software S4, and (ii) measured A1, affected A2 or manipulated A4.
2
In fact there exist no test functions, which allow users or test personnel to read data from the memory of the
TOE.
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(O7) Mode-switch as special bytes in the security area of the EEPROM defining the TOE
mode as test mode or user mode. The mode-switch (i) will be set A8 by the test software
S3 to change the test mode into the user mode and (ii) might be manipulated A4.
(O8) Sensor-switch as special bytes in the security area of the EEPROM enabling or disabling
the sensors protecting the TOE against affecting A2. The test-program S3 will (i) enable
A10 the sensor-switch activating the sensors or (ii) disable A11 the sensor-switch deacti-
vating the sensors. In addition the sensor-switch might be manipulated A4.
3.1.3 Access Modes and Methods
(A1) Measure O4 or O6: Measuring the dynamic signals generated by the TOE and gaining
information about the object O4 while being generated by the random number generator
and the object O6 while being processed by the CPU or the DES co-processor.
Note that signals to be measured may be generated only by the random number genera-
tor, by the CPU or by the DES co-processor processing data.
(A2) Affect O4 or O6: Affect means manipulation of the operational conditions of the TOE
out of the specified range. Affect O4 or O6 means to run the software on the CPU or to
use the random number generator or the DES co-processor while the voltage, clock or
temperature as TOE's operational conditions are out of the specified range. Malfunctions
of the CPU, random number generator, or the DES co-processor may violate the integrity
of the stored objects O2 (E2PROM part), O3, O5, O7 or O8.
(A3) Influence O4: Influence means to change the environmental conditions of the TOE as
voltage, clock or temperature within the specified range to violate the integrity of the ran-
dom number generator (O4).
Note that the random number generator uses analogue signal processing that may be in-
fluenced. It is guaranteed that digital signal processing of the CPU and the DES co-
processor are stable within the specified range of the voltage, clock or temperature as
TOE's operational conditions as voltage, clock or temperature.
(A4) Manipulate O1, O2, O3, O4, O5, O6, O7 or O8: Specific hardware manipulations, such
as connecting to the bus lines, measuring or changing the content of a memory cell and
modification of the internal circuitry. These manipulations include to modify the con-
tents of stored data in the ROM (O1, O2), E2PROM, RAM (O3), OTP O5, O7 or O8
by means of changing the environmental conditions of the TOE out of the specified range
of the TOE's operational conditions, when no software is running on the TOE.
(A5) Execute O1 or O2: Execute the object O1 (as test software S3) or the object O2 (as the
application software S4) means in the context of the security policy (i) to write O2, (ii) to
read or to write O3, (iii) to read O4, (iv) to read or to set O5, or (v) to process O6
(A6) Read O3, O4, or O5: Read means to read the data from the storage media (E2PROM,
RAM O3, or OTP O5,) or the SFR (O4), and to be able output the information as the
test software S3 or the application software S4 running on the TOE.
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(A7) Write O2 or O3: Write means to modify the data in the storage media (E2PROM, RAM)
by the software running on the TOE (i. e. S3 or S4). The E2PROM contains parts of O2
and O3. The RAM contains parts of O3.
(A8) Set O5 or O7: Set the object O5 means to write logical 1 into a bit of the OTP by means
of the running software (i. e. the test software S3 or the application software S4). Set the
object O7 means to change the mode- switch that the TOE detects the user mode after
setting.
Note that reset (i. e. write logical 0) a bit of the OTP is not possible due to the TOE de-
sign.
(A9) Process O6: The information O6 is processed in the CPU and the DES co-processor by
the test software S3 or by the application software S4.
(A10) Enabling O8: Enabling the sensor-switch activates the sensors protecting the TOE against
affecting A2.
(A11) Disabling O8: Disabling the sensor-switch deactivates the sensors protecting the TOE
against affecting A2.
The Table 2 provides an overview of the access methods based on the technical opportunities of
the subjects. The access methods A1, A2, A3, A4 and A5 are performed form outside the TOE
and ascribed to the subjects S1 and S2. The access methods A6, A7, A8, A9, A10 and A11 are
performed by software running on the TOE and ascribed to the subjects S3 and S4.
O1 O2 O3 O4 O5 O6 O7 O8
S1 A4, A5 A4, A5 A4 A1, A2, A3, A4 A4 A1, A2, A4 A4 A4
S2 A4, A5 A4, A5 A4 A1, A2, A3, A4 A4 A1, A2, A4 A4 A4
S3 - A7*1
A6, A7 A6 A6, A8 A9 A8 A10, A11
S4 - A7*2
A6, A7 A6 A6, A8 A9 A8*3
A10, A11
Table 2: All access methods, which have to be considered
*1
The test software is able to store data in the EEPROM after the tests are finished. These data
can be a part of the application software. The customer is responsible for the data stored in the
EEPROM at the end of the test process of phase 3.
*2
The application software stored in the ROM will be able to store additional data in the
EEPROM that can be executed. The software developer is responsible for this security relevant
item. This is therefore not in the scope of this evaluation.
*3
The application software is able to set bits in one part of OTP area that is not write protected
but can not be erased based on the hardware design. The mode-switch and the sensor-switch
are stored in an additional part of the OTP that is read only (write and erase not possible for
the Application Software, based on the hardware design) and can only be written during the
test mode.
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3.2 Assets
No additional assets to those already defined in the protection profile were identified.
The objects defined in the preceding section are specific instances of some of these assets.
3.3 Assumptions
Since this Security Target claims conformance to the protection profile PP/9806, the assumptions
defined in section 3.2 of the protection profile are valid for this Security Target.
This section defines specific additional assumptions for this ST.
Assumption on phase 1:
A.SOFT_FUNC The embedded software running on the TOE in phases 4 to 7 checks the
integrity of the user data stored on the TOE and responses appropriately
in case of loss of integrity due to errors. The software shall react ade-
quately to the output signals of the protection mechanisms provided by
the TOE.
Note, that this is an assumption for Phase 1, because the application software developer is as-
sumed to implement these properties correctly during phase 1. It can be seen as a special case of
A.SOFT_ARCHI (see PP/9806, section 3.2.1), however it is stated on its own for additional
clarity.
Assumption on phase 4 to 6:
A.SCRAP_MARKED All ICs marked as non functional by Philips on the wafers delivered to
the IC packaging manufacturer will be destroyed (“scraped”) under con-
trolled conditions.
This assumption can be seen as a special case of the assumptions on the delivery process (see
PP/9806, section 3.2.2), however it is stated on its own for additional clarity.
3.4 Threats
Since this Security Target claims conformance to the protection profile PP/9806, the threats de-
fined in section 3.3 of the protection profile are valid for this Security Target.
No additional threats where identified, which are not already defined in the protection profile.
3.5 Organisational Security Policies
As stated in the protection profile, specifications of organisational security policies depend essen-
tially on the applications in which the TOE is incorporated. Therefore, no organisational security
policy is defined in this Security Target. All security objectives are derived solely from the threats.
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4 Security Objectives
The chapter Security Objectives is divided into the following sections: “Security Objectives for
the TOE” and “Security Objectives for the Environment”.
4.1 Security Objectives for the TOE
The security objectives defined in section 4.1 of the protection profile are valid for the TOE. In
the following the security objectives defined in the PP/9806 are reorganised into specific security
objectives
Note: The TOE security objectives have to be supported by the environment. For example
O.CLON can be supported by the TOE itself only in so far that the information needed
for cloning cannot be derived from the TOE itself. That this information cannot be stolen
from the development and production sites cannot be guaranteed by technical mecha-
nisms of the TOE itself. Similarly O.DIS_MEMORY and O.MOD_MEMORY have to
be supported by the application software since the TOE cannot prevent a badly designed
application software from corrupting or disclosing its own sensitive data.
O.CLON can be seen as a combination of O.DIS_MEMORY, O.TAMPER,
O.DIS_MECHANISM.
This note is not specific for this Security Target but obviously holds already for the general situa-
tion described in the protection profile.
The following specific security objectives (SO1) – (SO5) reorganise the objectives listed in the
PP/9806 and include additional objectives regarding control- and crypto-functions. The Security
Policy used by some Security Functional Requirements (see chapter 5.1.1.1) will be based on
these security objectives.
(SO1) Mode Control (Introduces Mode Control and covers special aspects of O.OPERATE by
providing test functionality in Test Mode and special aspects of O.DIS_MEMORY and
O.MOD_MEMORY by preventing the use of test functions in User Mode)
The TOE shall provide test functionality and allow the administrator S1 to execute the
test software in the test mode.
The TOE shall allow the end-user S2 to execute the application software in the user
mode.
The TOE shall prevent that an end-user S2 executes the test software in the user mode
and doing so:
(a) to read out the application data independently of the read access provided by the ap-
plication software.
(b) to write the application data with chosen values independently of the write access
provided by the application software,
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(c) to set the configuration data independently of the application software,
(d) to read random numbers independently of the application software,
(e) to process information of the application data and the random numbers independ-
ently of the application software.
(SO2) Operating Conditions Control (Covers O.OPERATE)
The TOE allows the execution of the application software in specified range of the opera-
tional condition of the TOE. The TOE shall prevent malfunctions during execution of
the application software in the user mode forced by the operating parameters voltage sup-
plied, frequency of the clock or temperature of the chip, which are out of the specified
range of the operational condition. If the TOE is configured to control the operating pa-
rameters and one of these parameters are out of the specified range then the TOE shall re-
set the actual running program.
(SO3) Tamper Proof (Covers O.FLAW, O.TAMPER and thereby also O.DIS_MECHANISM,
O.DIS_MEMORY, O.MOD_MEMORY)
The construction of the TOE shall resist manipulation to withstand attacks trying to ma-
nipulate the hardware and disable security enforcing functions of the TOE in the user
mode.
The construction of the TOE shall prevent that an attacker is able to manipulate (i) the
test software in the ROM, (ii) the application software in the ROM and the E2PROM,
(iii) the application data in the E2PROM and RAM, (iv) the configuration data in the
OTP and (v) the mode-switch when the chip is in the user mode.
The construction of the TOE shall avert the analysis of the design in the user mode to
prevent cloning of the TOE hardware.
(SO4) Non-existence of Information Leakage (Covers aspects of O.FLAW and adds support
against disclosure of user data during the correct processing)
The TOE must not contain flaws in the design, implementation or operation that cause
Information Leakage. The TOE’s hardware construction and test-software design shall en-
sure that it does not disclose data processed by means of the CPU, the DES co-processor
or the RNG. This means that during the user mode no static or dynamic signals are gen-
erated that can be measured and analysed by an attacker using the physical external inter-
face or that an attacker is able to disclose data based on a flaw using the physical external
interface or the surface of the smartcard IC.
(SO5) Cryptographic support (Additional Objective, introduces support by the Random Num-
ber Generator and the DEA co-processor)
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(a) Bytes read from the TOE’s random number generator in the user mode shall be un-
predictable.
(b) The TOE shall provide a tamper resistant Triple-DES implementation.
4.2 Security Objectives for the Environment
Since this Security Target claims conformance to the protection profile PP/9806, the objectives
defined in section 4.2 of the protection profile are valid for this Security Target.
Note that according to the note in the preceding subsection the application software, which is a
part of the environment, has to support all security objectives of the TOE.
The following additional objective for the environment is identified (which is relevant for the
phases 2 - 6:
OE.SCRAP_DEFECT Appropriate methods are established to destroy all defect ICs and pre-
finished smart cards. The non functional IC, which marked on the de-
livered wafers, and the defect smart cards identified according to
O.TEST_OPERATE will be scraped under controlled conditions by
the responsible manufacturer of that phase.
Note that this objective can be seen as a special aspect of O.TEST_OPERATE. It is also de-
scribed as part of the text of PP/9806, section 2.3.2. However, it was added as an explicit objec-
tive for clarity.
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5 IT Security Requirements
The chapter IT Security Requirements is divided into the following sections and subsections:
“TOE Security Requirements” and “Security Requirements for the Environment”.
5.1 TOE Security Requirements
5.1.1 TOE Security Functional Requirements
5.1.1.1 Definition of Security Policies used in Security Functional Requirements
Some of the SFRs defined for the TOE require access policies to be defined. This is done in this
section.
The security policy informally defined by the security objectives (SO1) to (SO5) in section 4.1
can be described semiformally as follows:
SO1 Mode Control
The TOE shall allow the access-sets (S1, A5, O1) and (S3, A7, O2) in the test mode as
well as (S2, A5, O2) in the user mode.
The TOE shall prevent access-sets (S1, A5, O2) in the test mode as well as (S2, A5, O1)
and (S4, A8, O7).
The external security measure A.SOFT_ARCHI prevents (S4, A7, O2) in the user mode.
SO2 Operating Conditions Control
If the sensor-switch O8 is enabled A10 then for the test mode as well as for the user mode
(a) the TOE shall prevent the access-sets (S1, A2, O4), (S1, A2, O6), (S2, A2, O4) and
(S2, A2, O6) and
(b) if A2 is detected the TOE shall prevent the access sets (S2, A5, O1), (S2, A5,O2),
(S3, A6, O3), (S3, A6, O4), (S3, A6, O5), (S3, A7, O2), (S3, A7, O3), (S3, A8, O5),
(S3, A9, O6), (S4, A6, O3), (S4, A6, O4), (S4, A6, O5), (S4, A7, O2), (S4, A7, O3),
(S4, A8, O5) and (S4, A9, O6).
SO3 Tamper Proof
The TOE shall prevent access-sets (S1, A4, O1), (S1, A4, O2), (S1, A4, O3),
(S1, A4, O4), (S1, A4, O5), (S1, A4, O6), (S1, A4, O7), (S1, A4, O8), (S2, A4, O1),
(S2, A4, O2), (S2, A4, O3), (S2, A4, O4), (S2, A4, O5), (S2, A4, O6), (S2, A4, O7) and
(S2, A4, O8) in the user mode as well as in the test mode.
SO4 Non-existence of Information Leakage
The TOE shall prevent the access-sets (S1, A1, O4) and (S1, A1, O6) in the test mode as
well as (S2, A1, O4) and (S2, A1, O6) in the user mode.
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SO5 Cryptographic support
The TOE shall allow the access-sets (S3, A6, O4), (S4, A6, O4), (S3, A9, O6) and
(S4, A9, O6) where S3 has permission only in the test mode and S4 has permission only
in the user mode.
The TOE shall prevent the access-sets (S1, A1, O4), (S1, A2, O4), (S1, A3, O4),
(S1, A4, O4), (S2, A1, O4), (S2, A2, O4), (S2, A3, O4) and (S2, A4, O4) as well as the
access-sets (S1, A1, O6) (S1, A2, O6), (S1, A4, O6), (S2, A1, O6), (S2, A2, O6) and
(S2, A4, O6) in the test mode and in the user mode.
The security objectives imply the following security policies:
SP1 Tamper Protection Security Policy
SP1.1 The TOE shall prevent any access-method measuring A1, influencing A3 and manipu-
lating A4 for all objects which may be accessed by these methods.
The SP1 is described by the following list of access-sets prevented by the TOE:
(S1, A1, O4), (S1, A1, O6), (S1, A3, O4), (S1, A4, O1), (S1, A4, O2), (S1, A4, O3), (S1,
A4, O4), (S1, A4, O5), (S1, A4, O6), (S1, A4, O7), (S1, A4, O8), (S2, A1, O4), (S2, A1,
O6), (S2, A3, O4), (S2, A4, O1), (S2, A4, O2), (S2, A4, O3), (S2, A4, O4), (S2, A4,
O5), (S2, A4, O6), (S2, A4, O7) and (S2, A4, O8).
SP1.2 The TOE shall prevent successful affecting A2 (i) in the Test mode (S1, A2, O4), (S1,
A2, O6) if the sensor-switch is enabled, and (ii) in the User mode (S2, A2, O4), (S2, A2,
O6).3
If attempted affecting A2 is detected the TOE shall prevent the access sets (S2, A5, O1)
and (S2, A5,O2). Moreover, it shall close the running program (this prevents all other ac-
cess-sets listed in SO2 (b) above).
SP2 Test Mode Security Policy
In the test mode the administrator S1 is permitted to execute A5 the test software O1.
The test software as subject S3 is permitted to access the objects O2, O3, O4, O5, O6,
O7 and O8 as described by Table 3. The TOE shall prevent the access-sets described by
Table 4.
SP3 User Mode Security Policy
In the user mode the end-user S2 is permitted to execute A5 the application software O2.
The application software as subject S4 is permitted to access the objects O3, O4, O5, O6,
3
Note that due to the assumption A.DEV_ORG the integrity of the TOE will be ensured by the test environ-
ment if the TOE is used out of the specified range of the operational condition.
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O7 and O8 as described by Table 5. The TOE shall prevent the access-sets described by
Table 6.
O1 O2 O3 O4 O5 O6 O7 O8
S1 A5 X* X* X* X* X* X*
S2 X* X* X* X* X* X*
S3 A7 A6, A7 A6 A6, A8 A9 A8 A10, A11
S4
Table
Table
Table
Table 3
3
3
3: Allowed access according to the
: Allowed access according to the
: Allowed access according to the
: Allowed access according to the Test Mode Security Policy
Test Mode Security Policy
Test Mode Security Policy
Test Mode Security Policy
X*This combination is not applicable regarding the regular access modes A5 to A11 that can be
controlled by the chip.
O1 O2 O3 O4 O5 O6 O7 O8
S1 A5 X* X* X* X* X* X*
S2 A5 A5 X* X* X* X* X* X*
S3
S4 A7 A6, A7 A6 A6, A8 A9 A8 A10, A11
Table
Table
Table
Table 4
4
4
4: Prevented access according to the
: Prevented access according to the
: Prevented access according to the
: Prevented access according to the Test Mode Security Policy
Test Mode Security Policy
Test Mode Security Policy
Test Mode Security Policy
X*This combination is not applicable regarding the regular access modes A5 to A11 that can be
controlled by the chip.
O1 O2 O3 O4 O5 O6 O7 O8
S1 X* X* X* X* X* X*
S2 A5 X* X* X* X* X* X*
S3
S4 A7*1
A6, A7 A6 A6, A8 A9
Table
Table
Table
Table 5
5
5
5: Allowed access according to the
: Allowed access according to the
: Allowed access according to the
: Allowed access according to the User Mode Security Policy
User Mode Security Policy
User Mode Security Policy
User Mode Security Policy
X*This combination is not applicable regarding the regular access modes A5 to A11 that can be
controlled by the chip.
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*1
Note that this is a security relevant option based on the decision of the software developer.
O1 O2 O3 O4 O5 O6 O7 O8
S1 A5 A5 X* X* X* X* X* X*
S2 A5 X* X* X* X* X* X*
S3 A7 A6, A7 A6 A6, A8 A9 A8 A10, A11
S4 A8 A10, A11
Table
Table
Table
Table 6
6
6
6: Prevented access according to the
: Prevented access according to the
: Prevented access according to the
: Prevented access according to the User Mode Security Policy
User Mode Security Policy
User Mode Security Policy
User Mode Security Policy
X*This combination is not applicable regarding the regular access modes A5 to A11 that can be
controlled by the chip.
5.1.1.2 TOE Security Functional Requirements already contained in the PP/9806
and applicable to Phase 3 only
The SFRs already specified in the protection profile PP/9806, which are applicable to phase 3
only, are listed in this subsection. The assignment and selection operations, which were left open
in the PP, are completed here. Additionally for every SFR a refinement is stated, which serves as a
short explanation of the relevance for the specific TOE.
FIA_UAU.2 User authentication before any action
FIA_UAU.2 User authentication before any action
FIA_UAU.2 User authentication before any action
FIA_UAU.2 User authentication before any action
FIA_UAU.2.1 The TSF shall require each user to be successfully authenticated before allowing
any other TSF-mediated actions on behalf of that user.
Dependencies: FIA_UID.1 Timing of identification
(No operations necessary.)
Refinement: For the TOE this means that the test engineer S1 will have be authenticated before
execution of test functions by the test ROM. The end-user S2 will be authenticated implicitly by
the TOE as anybody, who is not authenticated as a test engineer. S2 cannot execute security rele-
vant functions of the TOE (S2 stands for anybody including potential attackers).
Note, that the decision, which security relevant functions provided by the user ROM (application
software) an end-user is allowed to use, is outside of the control of the TOE. It has to be con-
trolled by suitable functions of the user ROM itself.
FIA_UID.2 User identification before any action
FIA_UID.2 User identification before any action
FIA_UID.2 User identification before any action
FIA_UID.2 User identification before any action
Hierarchical to: FIA_UID.1
FIA_UID.2.1 The TSF shall require each user to identify itself before allowing any other TSF-
mediated actions on behalf of that user.
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Dependencies: No dependencies.
(No operations necessary.)
Refinement: This identification is done implicitly with help of the flag “mode-switch” which is
changed during the TOE life-cycle at the end of phase 3 from test mode into the user mode:
The controlled environment within phase 3 limits TOE access to the administrator. Moreover,
the administrator S1 is implicitly identified by the TOE during authentication, before test func-
tions can be used. The user mode is active during phase 4 to 7. In this mode everybody is identi-
fied implicitly as end-user (which is the same as “anybody”) S2.
From user mode the TOE cannot be switched back into test mode.
FIA_ATD.1 User attribute definition
FIA_ATD.1 User attribute definition
FIA_ATD.1 User attribute definition
FIA_ATD.1 User attribute definition
Hierarchical to: No other components.
FIA_ATD.1.1 The TSF shall maintain the following list of security attributes belonging to
individual users: administrator or end-user 4
.
Dependencies: No dependencies.
Refinement: The TOE will distinguish only between administrators S1 and end-users S2. No
further user attributes besides these role-names are necessary. All properties of these roles are de-
fined statically and implicitly.
FPT_TST.1 TSF testing
FPT_TST.1 TSF testing
FPT_TST.1 TSF testing
FPT_TST.1 TSF testing
Hierarchical to: No other components.
FPT_TST.1.1 The TSF shall run a suite of self tests at the request of the authorised user S1, at
the conditions test mode5
to demonstrate the correct operation of the TSF.
FPT_TST.1.2 The TSF shall provide authorised users with the capability to verify the integrity of
TSF data.
FPT_TST.1.3 The TSF shall provide authorised users with the capability to verify the integrity of
stored TSF executable code.
Dependencies: FPT_AMT.1 Abstract machine testing
Refinement: At the end of phase 3 the test engineer S1 can initiate a suite of self tests demon-
strating correct operation of the TSF and checking integrity of the IC dedicated software (the test
ROM content) and data. This is possible only in test mode.
4
[assignment: list of security attributes]
5
[selection: during initial start-up, periodically during normal operation, at the request of the authorised user, at
the conditions [assignment: conditions under which self test should occur]]
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FDP_SDI.1 Stored data integrity monitoring
FDP_SDI.1 Stored data integrity monitoring
FDP_SDI.1 Stored data integrity monitoring
FDP_SDI.1 Stored data integrity monitoring
Hierarchical to: No other components.
FDP_SDI.1.1 The TSF shall monitor user data stored within the TSC for integrity errors6
on all
objects, based on the following attributes: all user data7
.
Dependencies: No dependencies.
Refinement: The production testing at the end of phase 3 includes functions, which allow to
check the integrity of the user ROM. Moreover the test functions used to write user data into the
EEPROM of the TOE check the correctness of these data after writing. All user data are checked,
therefore no specific attributes have to be defined.
5.1.1.3 TOE Security Functional Requirements already contained in the PP/9806
and applicable to Phases 3 to 7
The SFRs already specified in the protection profile PP/9806, which are applicable to phase 3 to
7, are listed in this subsection. The assignment and selection operations, which were left open in
the PP, are completed here. Additionally for every SFR a refinement is stated, which serves as a
short explanation of the relevance for the specific TOE.
FMT_MOF.1 Management of security functions behaviour
FMT_MOF.1 Management of security functions behaviour
FMT_MOF.1 Management of security functions behaviour
FMT_MOF.1 Management of security functions behaviour
Hierarchical to: No other components.
FMT_MOF.1.1 The TSF shall restrict the ability to disable 8
the functions sensors 9
to the ad-
ministrator 10
.
Dependencies: FMT_SMR.1 Security roles
Refinement: The administrator S1 can only disable the sensors in test mode. They are enabled
automatically when the TOE is switched to user mode. In user mode the sensors are permanently
active and cannot be disabled by S1 or S2.
FMT_MSA.1 Management of security attributes
FMT_MSA.1 Management of security attributes
FMT_MSA.1 Management of security attributes
FMT_MSA.1 Management of security attributes
Hierarchical to: No other components.
FMT_MSA.1.1 The TSF shall enforce the Mode-Control-Policy11
to restrict the ability to mod-
ify 12
the security attributes mode-switch (O7)13
to administrator S1 14
.
6
[assignment: integrity errors]
7
[assignment: user data attributes]
8
[selection: determine the behaviour of, disable, enable, modify the behaviour of]
9
[assignment: list of functions]
10
[assignment: the authorised identified roles]
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Dependencies: [FDP_ACC.1 Subset access control or
FDP_IFC.1 Subset information flow control] 15
FMT_SMR.1 Security roles
Refinement: The Mode-Control-Policy
Mode-Control-Policy
Mode-Control-Policy
Mode-Control-Policy is an access control policy defined as the combination of
the Test Mode Security Policy and the User Mode Security Policy as defined in section 5.1.1.1.
Note that the policy in fact doesn’t allow the administrator to modify the mode-switch directly
(access type A4). The administrator can only start the test software (access type A5 to O1) and
can then call a test function, by which the test software (as S3) modifies (access A8) the mode-
switch (O7)
FMT_SMR.1 Security roles
FMT_SMR.1 Security roles
FMT_SMR.1 Security roles
FMT_SMR.1 Security roles
Hierarchical to: No other components.
FMT_SMR.1.1 The TSF shall maintain the roles the administrator S1 and the end-user S2 16
.
FMT_SMR.1.2 The TSF shall be able to associate users with roles.
Dependencies: FIA_UID.1 Timing of identification
Refinement: The roles administrator S1 and end user S2 are fixed roles defined by the behaviour
of the TOE in test mode and user mode. Users are associated with roles by using different oper-
ating modes in the TOE life-cycle (test mode phase 3 and user mode in phase 4 to 7) and implic-
itly by authentication in test mode: Every user, who can authenticate himself in test mode by
using the correct password associated with a test function, is automatically associated with the role
administrator, while every user is associated with the role end-user in user mode.
FMT_MSA.3 Static attribute initialisation
FMT_MSA.3 Static attribute initialisation
FMT_MSA.3 Static attribute initialisation
FMT_MSA.3 Static attribute initialisation
Hierarchical to: No other components.
FMT_MSA.3.1 The TSF shall enforce the Mode-Control-Policy17
to provide fixed18
default val-
ues for security attributes that are used to enforce the SFP.
11
[assignment: access control SFP, information flow control SFP]
12
[selection: change_default, query, modify, delete, [assignment: other operations]]
13
[assignment: list of security attributes]
14
[assignment: the authorised identified roles]
15
Subset FDP_ACC.1 is selected in this Security Target and is included in FDP_ACC.2. Therefore FDP_IFC.1
and the dependency FDP_IFF.1 is not described in this Security Target.
16
[assignment: the authorised identified roles]
17
[assignment: access control SFP, information flow control SFP]
18
[selection: restrictive, permissive, other property]
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FMT_MSA.3.2 The TSF shall allow the administrator S1 19
to specify alternative initial values to
override the default values when an object or information is created.
Dependencies: FMT_MSA.1 Management of security attributes
FMT_SMR.1 Security roles
Refinement: The Mode-Control-Policy
Mode-Control-Policy
Mode-Control-Policy
Mode-Control-Policy is an access control policy defined as the combination of
the Test Mode Security Policy and the User Mode Security Policy as defined in section 5.1.1.1.
The only security attribute used to enforce the SFP is the global security attribute “mode-switch”.
According to the policy this mode-switch is set to “Test Mode” as a default, when the TOE is
produced.
This value can be seen as a “permissive” value, since testing is possible. On the other hand the
value can also be seen as a “restrictive” value, since the subject anybody [S2, same as end-user]
cannot use security functions. In any way it is the default value required by the policy and there-
fore the authors used the word “fixed” as “other property” in this selection.
FDP_ACC.2 Complete access control
FDP_ACC.2 Complete access control
FDP_ACC.2 Complete access control
FDP_ACC.2 Complete access control
Hierarchical to: FDP_ACC.1
FDP_ACC.2.1 The TSF shall enforce the Mode-Control-Policy and the Tamper Protection Se-
curity Policy 20
on the subjects S1 - S4 and the objects O1 - O8 21
and all operations among sub-
jects and objects covered by the SFP.
FDP_ACC.2.2 The TSF shall ensure that all operations between any subject in the TSC and any
object within the TSC are covered by an access control SFP.
Dependencies: FDP_ACF.1 Security attribute based access control
Refinement: The Mode-Control-Policy
Mode-Control-Policy
Mode-Control-Policy
Mode-Control-Policy is an access control policy defined as the combination of
the Test Mode Security Policy and the User Mode Security Policy as defined in section 5.1.1.1.
The Tamper Protection Security Policy
Tamper Protection Security Policy
Tamper Protection Security Policy
Tamper Protection Security Policy is also defined in section 5.1.1.1. The subjects, objects
and access methods in the TSC are defined in section 3.1.
FDP_ACF.1 Security attribute based access control
FDP_ACF.1 Security attribute based access control
FDP_ACF.1 Security attribute based access control
FDP_ACF.1 Security attribute based access control
Hierarchical to: No other components.
FDP_ACF.1.1 The TSF shall enforce the Mode-Control-Policy and the Tamper Protection Secu-
rity Policy 22
to objects based on mode-switch 23
.
19
[assignment: the authorised identified roles]
20
[assignment: access control SFP]
21
[assignment: list of subjects and objects]
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FDP_ACF.1.2 The TSF shall enforce the following rules to determine if an operation among
controlled subjects and controlled objects is allowed: (i) in the Test Mode as de-
scribed in Table 3 (ii) in the User Mode as described in Table 5 24
.
FDP_ACF.1.3 The TSF shall explicitly authorise access of subjects to objects based on the fol-
lowing additional rules:
(i) The TOE allows the administrator S1 to change the mode-switch from the
Test mode into the User Mode.
(ii) The TOE prevents the administrator S1 and the end-user S2 to change the
mode-switch from the User mode into the Test Mode. 25
.
FDP_ACF.1.4 The TSF shall explicitly deny access of subjects to objects based on the (i) rules
defined for the Tamper Protection Security Policy in section 5.1.1.1, (ii) in the
Test Mode as described in Table 4, (iii) in the User Mode as described in Table
626
.
Dependencies: FDP_ACC.1 Subset access control
FMT_MSA.3 Static attribute initialisation
Refinement: The Mode-Control-Policy
Mode-Control-Policy
Mode-Control-Policy
Mode-Control-Policy is an access control policy defined as the combination of
the Test Mode Security Policy and the User Mode Security Policy as defined in section 5.1.1.1.
The Tamper Protection Security Policy
Tamper Protection Security Policy
Tamper Protection Security Policy
Tamper Protection Security Policy is also defined in section 5.1.1.1. The subjects, objects
and access methods in the TSC are defined in section 3.1.
FDP_IFC.1 Subset information flow control
FDP_IFC.1 Subset information flow control
FDP_IFC.1 Subset information flow control
FDP_IFC.1 Subset information flow control
Hierarchical to: No other components.
FDP_IFC.1.1 The TSF shall enforce the SFPchip
27
on S3 and S4 28
.
Dependencies: FDP_IFF.1 Simple security attributes
Refinement: The following information flow control SFPchip shall be enforced by the TSF:
• The information flow from subject S4 to S3 during the user mode is denied.
22
[assignment: access control SFP]
23
[assignment: security attributes, named groups of security attributes]
24
[assignment: rules governing access among controlled subjects and controlled objects using controlled operations
on controlled objects]
25
[assignment: rules, based on security attributes, that explicitly authorise access of subjects to objects]
26
[assignment: rules, based on security attributes, that explicitly deny access of subjects to objects]
27
[assignment: information flow control SFP]
28
[assignment: list of subjects, information, and operations that cause controlled information to flow to and from
controlled subjects covered by the SFP]
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• S3 shall be able to store customer specific data in the EEPROM-memory that can be accessed
by S4 in the user mode. S3 is only permitted to store user data when the TOE is in the test
mode.
• The access of S4 to data and software stored in the EEPROM or in the RAM shall be denied
during the test mode performed by S3.
Note: Since the security policies defined in section 5.1.1.1 already include all possibilities for
subjects to get access to information (in the form of data objects), the SFPchip is only an explicit
repetition of parts of these policies.
FDP_IFF.1 Simple security attributes
FDP_IFF.1 Simple security attributes
FDP_IFF.1 Simple security attributes
FDP_IFF.1 Simple security attributes
Hierarchical to: No other components.
FDP_IFF.1.1 The TSF shall enforce the SFPchip
29
based on the following types of subject and
information security attributes: S3 or S4 and the mode-switch30
.
FDP_IFF.1.2 The TSF shall permit an information flow between a controlled subject and con-
trolled information via a controlled operation if the following rules hold: see SFPchip
31
.
FDP_IFF.1.3 The TSF shall enforce the no additional information flow control rules 32
.
FDP_IFF.1.4 The TSF shall provide no additional SFP capabilities 33
.
FDP_IFF.1.5 The TSF shall explicitly authorise an information flow based on the following
rules: see SFPchip
34
.
FDP_IFF.1.6 The TSF shall explicitly deny an information flow based on the following rules: see
SFPchip
35
.
Dependencies: FDP_IFC.1 Subset information flow control
FMT_MSA.3 Static attribute initialisation
Refinement: For the definition of SFPchip see the preceding SFR.
29
[assignment: information flow control SFP]
30
[assignment: the minimum number and type of security attributes]
31
[assignment: for each operation, the security attribute-based relationship that must hold between subject and
information security attributes]
32
[assignment: additional information flow control SFP rules]
33
[assignment: list of additional SFP capabilities]
34
[assignment: rules, based on security attributes, that explicitly authorise information flows]
35
[assignment: rules, based on security attributes, that explicitly deny information flows]
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FAU_SAA.1 Potential violation analysis
FAU_SAA.1 Potential violation analysis
FAU_SAA.1 Potential violation analysis
FAU_SAA.1 Potential violation analysis
Hierarchical to: No other components.
FAU_SAA.1.1 The TSF shall be able to apply a set of rules in monitoring the audited events and
based upon these rules indicate a potential violation of the TSP.
FAU_SAA.1.2 The TSF shall enforce the following rules for monitoring audited events:
a) Accumulation or combination of
(1) low frequency of clock input (under approximately 800 kHz) or,
(2) high frequency of clock input (over 10 MHz) or,
(3) low voltage power supply (under 2,7 V) or
(4) high voltage power supply (over 5,5 V) or
(5) low temperature (under– 25 °C) or
(6) high temperature (over +85°C) or
(7) high voltage for the write process to the EEPROM 36
.
known to indicate a potential security violation;
b) no other rules.
Dependencies: FAU_GEN.1 Audit data generation
Refinement: --
Note that the PP/9806 states that the dependency of FAU_SAA.1 with FAU_GEN.1 is not ap-
plicable to the TOE; the FAU_GEN component forces many security relevant events to be re-
corded (due to dependencies with other functional security components) and this is not achiev-
able to a smartcard IC considering state-of-the-art implementation. It is then assumed that the
function FAU_SAA.1 may still be used and the specific audited events will have to be defined in
the ST independently with FAU_GEN.1. Refer to section 8.2.2.
FPR_UNO.1 Unobservability
FPR_UNO.1 Unobservability
FPR_UNO.1 Unobservability
FPR_UNO.1 Unobservability
Hierarchical to: No other components.
FPR_UNO.1.1 The TSF shall ensure that S1 and S2 37
are unable to observe the operation A9 38
on O6 39
by S3 or S4 40
.
Dependencies: No dependencies.
36
[assignment: subset of defined auditable events]
37
[assignment: list of users and/or subjects]
38
[assignment: list of operations]
39
[assignment: list of objects]
40
[assignment: list of protected users and/or subjects]
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Refinement: The unobservability scenario “Measuring the external behaviour during the Triple-
DES-operation or the CPU-operation” A1 includes:
(1) Differential Power Analysis,
(2) Timing Attacks
Note: The start of the DES-coprocessor can be observed but is not a security relevant operation.
FPT_PHP.2 Notification of physical attack
FPT_PHP.2 Notification of physical attack
FPT_PHP.2 Notification of physical attack
FPT_PHP.2 Notification of physical attack
Hierarchical to: FPT_PHP.1
FPT_PHP.2.1 The TSF shall provide unambiguous detection of physical tampering that might
compromise the TSF.
FPT_PHP.2.2 The TSF shall provide the capability to determine whether physical tampering
with the TSF’s devices or TSF’s elements has occurred.
FPT_PHP.2.3 For the power supply block, the internal frequency generation and the chip tem-
perature 41
, the TSF shall monitor the devices and elements and notify a reset42
when physical tampering with the TSF’s devices or TSF’s elements has occurred.
Dependencies: FMT_MOF.1 Management of security functions behaviour
Refinement: In case of detected affecting, the TOE shall automatic respond preventing the access
sets (S1, A5, O1), (S1, A5,O2), (S2, A5, O1), (S2, A5,O2), (S3, A6, O4), (S3, A9, O6), (S4, A6,
O4) and (S4, A9, O6).
FPT_PHP.3 Resistance to physical attack
FPT_PHP.3 Resistance to physical attack
FPT_PHP.3 Resistance to physical attack
FPT_PHP.3 Resistance to physical attack
Hierarchical to: No other components.
FPT_PHP.3.1 The TSF shall resist the physical tampering scenario: Manipulation A4 43
to the
objects O1 - O8 44
by responding automatically such that the TSP is not violated.
Dependencies: No dependencies.
Refinement: For the Random Numbers O4 this shall also include the scenario that the attacker
tries to modify the quality of the random number generation by tampering attacks.
5.1.1.4 Additional TOE Security Functional Requirements
Additional SFRs, which are specific for this Security Target are specified in this subsection. These
SFRs are applicable from phases 3 to 7.
41
[assignment: list of TSF devices/elements for which active detection is required]
42
[assignment: a designated user or role]
43
[assignment: physical tampering scenarios]
44
[assignment: list of TSF devices/elements]
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In order to state the IT security functional requirement for the Random Number Generator of
the TOE an additional family (FCS_RND) of the Class FCS (cryptographic support) with a secu-
rity functional component FCS_RND.1 is defined in chapter 9.1 according to Annexes B and C
of Common Criteria Part 1 ([1]). This family FCS_RND Generation of random numbers de-
scribes the functional requirements for the generation of random numbers (i. e. read A6 the ob-
ject O4 in the context of this Security Target) used for cryptographic purposes.
FCS_RND.1 Quality metric for random numbers
FCS_RND.1 Quality metric for random numbers
FCS_RND.1 Quality metric for random numbers
FCS_RND.1 Quality metric for random numbers
FCS_RND.1.1 The TSF shall provide a mechanism to generate random numbers that
have an entropy of at least 7 bit in each byte 45
.
Dependencies: No dependencies.
Refinement: The entropy of the random numbers is measured by the Shannon-Entropy as fol-
lows:
å
=
⋅
−
=
255
0
2
log
i
i
i p
p
E , where i
p is the probability that the random number (which
takes values between 0 and 255) is equal to i .
FCS_COP.1 Cryptographic operation
FCS_COP.1 Cryptographic operation
FCS_COP.1 Cryptographic operation
FCS_COP.1 Cryptographic operation
Hierarchical to: No other components.
FCS_COP.1.1 The TSF shall perform encryption and decryption 46
in accordance with a
specified cryptographic algorithm Triple Data Encryption Algorithm
(TDEA) 47
and cryptographic key sizes of 112 bit 48
that meet the follow-
ing list of standards 49
:
U.S. Department of Commerce / National Bureau of Standards
Data Encryption Standard (DES), FIPS PUB 46-3, 1999 October 25,
keying option 2 and according to International Organization for Stan-
dardization: Banking – Key Management, International Standard ISO
8732 (1988), Chapter 12.1.3.
Dependencies: [FDP_ITC.1 Import of user data without security attributes or FCS_CKM.1 Crypto-
graphic key generation], FCS_CKM.4 Cryptographic key destruction, FMT_MSA.2 Secure security
attributes
45
[assignment: a defined quality metric]
46
[assignment: list of crypto-graphic operations]
47
[assignment: cryptographic algorithm]
48
[assignment: cryptographic key sizes]
49
[assignment: list of standards]
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Refinement: --
5.1.1.5 Explicit SOF claim
Since the assurance level is augmented with AVA_VLA.4 the required level for the Strength of Func-
tion of the above listed Security Functional Requirements level is “SOF-high”.
5.1.2 TOE Security Assurance Requirements
The protection profile PP/9806 claims the assurance level EAL 4 augmented by ADV_IMP.2,
ALC_DVS.2 and AVA_VLA.4.
This Security Target claims assurance level EAL 5 augmented by ALC_DVS.2, AVA_VLA.4 and
AVA_MSU.3.
Since ADV_IMP.2 is part of EAL 5, the claims of the PP are all either contained directly or ful-
filled by components hierarchical to them in the level claimed in this Security Target.
5.2 Security Requirements for the Environment
5.2.1 Security Requirements for the IT-Environment
The security objectives for the environment will be ensured by Non-IT security requirements
only (see the next subsection and the rationale, section 8.2).
5.2.2 Security Requirements for the Non-IT Environment
This section contains the Security Requirements for the general (Non-IT-) Environment.
Most of the security objectives for the environment defined in PP/9806, section 4.2 and the ad-
ditional objective OE.SCRAP_DEFECT defined in section 4.2 of this document are of an or-
ganisational type. Therefore they require the definition of suitable procedures and methods by the
parties involved in the smart card life cycle. These objectives are already stated in the form of re-
quirements (compare e. g. O.DEV_DIS in the PP, which starts “The IC designer must have pro-
cedures...”. Therefore it is not necessary to repeat all these requirements here. Instead, the general
requirement for the (Non-IT-) environment is to fulfil all requirements already contained in the
objectives.
Note: All measures that are related to requirements, which are directed to the IC design and
production process, will be included in the documents describing the methods for site se-
curity, configuration control and internal delivery.
There is one type of objectives, for which the question has to be considered, if they should be seen
as requirements for the IT-environment: These are the objectives, which have implications for the
Smartcard Embedded Software, which is a part of the IT-environment. In fact the PP/9806 con-
tains one objective of this type, O.SOFT_MECH. However, in fact this is not a direct technical
requirement for the embedded software itself, but a requirement for the developer of this soft-
ware. Therefore this Security Target doesn’t define Security Functional Requirements in the style
of CC, part 2 for this objective.
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A special case of the situation discussed above is the usage of the DEA-coprocessor provided by
the TOE (defined as a requirement as SFR FCS_COP.1 in section 5.1.1.4). Since this coproces-
sor gets the cryptographic keys from the Smartcard Embedded Software, the developer of this
software has to provide functions for a secure key management. This includes secure key genera-
tion or secure key import (depending on the application) and secure key destruction, where suit-
able.
It was considered, that these requirements should be defined as formal SFRs for the IT-
environment using the SFRs FDP_ITC.1 resp. FCS_CKM.1, FCS_CKM.4 and FMT_MSA.2
from CC, part 2, which are the SFRs appearing in the dependency list for FCS_COP.1.
However, since the smart card embedded software may vary heavily depending on the applica-
tion, for which it is written, it wasn’t seen as suitable to define formal technical requirements.
Instead the following requirement holds (which is in fact a special case of O.SOFT_MECH):
The Smartcard Embedded Software shall be designed and developed in a way, which ensures ade-
quate cryptographic key management. This can be measured by checking that the dependencies
for FCS_COP.1 defined in CC, Part2 are either
- fulfilled by (functions of the embedded software fulfilling) the SFRs listed above or
- by other functions which cover the dependencies in a different but sufficient way, where
the security needs of the application determine the interpretation of the term “sufficient”.
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6 TOE Summary Specification
This chapter is divided into the following sections: “TOE Security Functions”, “Assurance meas-
ures”.
6.1 TOE Security Functions
The TOE Security Functions (TSF) directly correspond to the TOE security functional require-
ments defined in chapter 5.1.1.
The following security functions are applicable to the phases 4 to 7.
Note: Some of the security functions are configured at the end of phase 3 and all security func-
tions are already active during the delivery from phase 3 to phase 4.
F.RNG: The random number generator continuously produces random numbers with a
length of one byte. Each byte will at least contain a 7 bit entropy. The TOE im-
plements the F.RNG by means of a physical hardware random number generator
working stable within the limits guaranteed by F.OPC (operational conditions).
The TOE provides random numbers according to the functionality class P2 as
defined in [5] with a strength of function (consistently with other claims) SOF-
high.
Note: The application software shall observe a minimum of 4800 internal clocks between reading
two random numbers.
F.DEA: The TOE provides the Triple Data Encryption Algorithm (TDEA) according to
the Data Encryption Standard (DES). F.DEA is a modular basic cryptographic
function which provides the TDEA algorithm as defined by FIPS PUB 46 by
means of a hardware co-processor and supports the 2-key Triple DEA algorithm
according to keying option 2 in FIPS PUB 46-3 [7]. The two 56 bit keys (112 bit)
for the 2-key Triple DES algorithm shall be provided by the application software.
For encryption the application software provides 8 bytes of the plain text and
F.DEA calculates 8 bytes cipher text. The calculation output is read by the appli-
cation software. For decryption the application software also provides 8 bytes of
cipher text and F.DEA calculates 8 bytes plain text. The calculation output is read
by application software.
The TSF provides specific implementation features to reduce leakage of confiden-
tial user and TSF data to ensure that attackers are unable to observe the keys and
plain text by measuring the external behaviour during the Triple-DES-operation.
F.OPC: The function F.OPC has the following sub-functions: A function that filters
power supply and clock input and a function that monitors the power supply, the
frequency of the clock and the temperature of the chip by means of sensors.
If one of these parameters is out of the specified range a reset of the actual running
program and a CPU reset will be initiated. Before TOE delivery the mode-switch
is set to user mode. In user mode the TOE enables the sensors automatically when
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operated. Furthermore it prevents that the application software disables the sen-
sors.
Beside these sensors the security function comprises an additional sensor to check
the high voltage for the write process to the EEPROM during every write se-
quence. The result of this sensor must be read from a Special Function Register
and does not force an automatic event (e.g. reset).
F.PHY: The function F.PHY protects the TOE against manipulation of (i) the hardware,
(ii) the IC Dedicated Test Software in the ROM, (iii) the Smartcard Embedded
Software in the ROM and the EEPROM, (iv) the application data in the
EEPROM and RAM, (v) the configuration data in the security row and (vi) the
mode-switch. It also protects secret user data against disclosure when stored in
EEPROM and RAM or while being processed by the TOE.
The protection of the TOE comprises different features of the construction which
makes a tamper attack more difficult. By this the security function F.PHY also
supports in general the secure implementation of all Security Functional Require-
ments defined in chapter 5.1.1.
Further the security function F.COMP maintains the security domain for its own
execution that protects it from interference and tampering by untrusted subjects
both in the Test Mode and in the User Mode. It also enforces the separation be-
tween the security domains of subjects within each mode.
The function F.COMP also provides test personnel during Phase 3 with the capa-
bility to store the identification and/or pre-personalisation data and/or supple-
ments of the Smartcard Embedded Software in the EEPROM.
F.COMP: The function F.COMP provides access control by means of TOE modes of op-
eration selected by a mode-switch: (i) Test Mode and (ii) User Mode. The TSF
F.COMP has two aspects:
- Access control: In the Test Mode the TOE (i) allows to execute the IC
Dedicated Test Software and (ii) prevents to execute the Smartcard Em-
bedded Software. In the User Mode the TOE (i) allows to execute the
Smartcard Embedded Software and (ii) prevents to execute the IC Dedi-
cated Test Software.
- Mode switch: The initial TOE mode is the Test Mode. The TOE allows
to change the mode-switch only one time from the Test Mode into the
User Mode. The TOE prevents to change the mode-switch from the User
mode into the Test Mode.
Further the security function F.COMP maintains the security domain for its own
execution that protects it from interference and tampering by untrusted subjects
both in the Test Mode and in the User Mode. It also enforces the separation be-
tween the security domains of subjects within each mode.
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The function F.COMP also provides test personnel during Phase 3 with the capa-
bility to store the identification and/or pre-personalisation data and/or supple-
ments of the Smartcard Embedded Software in the EEPROM.
The TSF F.TEST described below is only applicable in phase 3:
F.TEST: The TSF provides test functions to demonstrate the correct operation of the secu-
rity functions provided by the TOE. This is performed in the Test Mode by a
suite of self tests at the request of the authorised user. The test functions also allow
to check the integrity of the ROM content and the functions writing data into the
EEPROM check the correctness of the data written.
Note: In User Mode these test functions are not available.
SOF claim
According to the CEM [4] a Security Target shall identify all mechanisms which can be assessed
according to the assurance requirement AVA_SOF.1.
The following mechanisms contributing to these functions were identified, which can be analysed
for their permutational or probabilistic properties:
1. The output of the Random Number Generator F.RNG can be analysed with probabilistic
methods.
2. The quality of the mechanism contributing to the leakage attacks of F.DEA can be ana-
lysed using probabilistic methods on power consumption of the TOE.
Therefore an explicit SOF claim of “high” is made for these mechanisms.
Note, that the cryptographic algorithm of F.DEA can also be analysed with permutational or
probabilistic methods but that this is not in the scope of CC evaluations.
6.2 Assurance measures
Appropriate assurance measures will be employed to satisfy the security assurance requirements
defined in section TOE Security Assurance Requirements. The developer will provide documents
containing the measures and further information needed to examine conformance of the measures
to the assurance requirements. The following table gives a mapping between the assurance re-
quirements and the documents containing the information needed for the respective requirement
either directly or referring to further documents containing this information.
Document(s) containing
Document(s) containing
Document(s) containing
Document(s) containing
or referring the relevant
or referring the relevant
or referring the relevant
or referring the relevant
information
information
information
information
Input evidence according to CC Part
Input evidence according to CC Part
Input evidence according to CC Part
Input evidence according to CC Part 3,
3,
3,
3,
which is contained or referred to in the
which is contained or referred to in the
which is contained or referred to in the
which is contained or referred to in the
document(s)
document(s)
document(s)
document(s)
Input for assurance fam
Input for assurance fam
Input for assurance fam
Input for assurance fami
i
i
i-
-
-
-
lies (according to deve
lies (according to deve
lies (according to deve
lies (according to devel
l
l
l-
-
-
-
oper actions in CC Part 3)
oper actions in CC Part 3)
oper actions in CC Part 3)
oper actions in CC Part 3)
semiformal functional specification ADV_FSP
Functional Specification,
Data Sheet
correspondence analysis between the
TOE summary specification and the
functional specification
ADV_RCR
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Document(s) containing
Document(s) containing
Document(s) containing
Document(s) containing
or referring the relevant
or referring the relevant
or referring the relevant
or referring the relevant
information
information
information
information
Input evidence according to CC Part
Input evidence according to CC Part
Input evidence according to CC Part
Input evidence according to CC Part 3,
3,
3,
3,
which is contained or referred to in the
which is contained or referred to in the
which is contained or referred to in the
which is contained or referred to in the
document(s)
document(s)
document(s)
document(s)
Input for assurance fam
Input for assurance fam
Input for assurance fam
Input for assurance fami
i
i
i-
-
-
-
lies (according to deve
lies (according to deve
lies (according to deve
lies (according to devel
l
l
l-
-
-
-
oper actions in CC Part 3)
oper actions in CC Part 3)
oper actions in CC Part 3)
oper actions in CC Part 3)
Formal Model TSP model (formal) ADV_SPM
high-level design (semiformal) ADV_HLD
High Level Design,
Design Report
correspondence analysis between func-
tional specification and high-level design
ADV_RCR
low level design ADV_LLD
architectural description ADV_INT
correspondence analysis between high-
level design and low-level design
ADV_RCR
Correspondence Demon-
stration,
Design Report
correspondence analysis between low-
level design and implementation repre-
sentation
ADV_RCR
Implementation represen-
tation, Source Code
implementation representation ADV_IMP
configuration management documenta-
tion
ACM
development tools documentation
development security documentation
life cycle definition documentation
ALC
Quality Management
Manual and Security Man-
agement Manual
parts of the delivery documentation ADO
administrator guidance AGD_ADM, AVA_MSU
secure installation, generation, and start-
up procedures
ADO_IGS
user guidance AGD_USR, AVA_MSU
Guidance, Delivery and
Operation Manual, Data
Sheet
parts of the delivery documentation ADO_DEL
vulnerability assessment
covert channel analysis
Vulnerability Assessment
strength of function claims analysis
AVA
test documentation
Test Documentation
Roadmap, Verification
Test, Characterisation Re-
port, Electrical Test Speci-
fication
test coverage analysis
ATE
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Document(s) containing
Document(s) containing
Document(s) containing
Document(s) containing
or referring the relevant
or referring the relevant
or referring the relevant
or referring the relevant
information
information
information
information
Input evidence according to CC Part
Input evidence according to CC Part
Input evidence according to CC Part
Input evidence according to CC Part 3,
3,
3,
3,
which is contained or referred to in the
which is contained or referred to in the
which is contained or referred to in the
which is contained or referred to in the
document(s)
document(s)
document(s)
document(s)
Input for assurance fam
Input for assurance fam
Input for assurance fam
Input for assurance fami
i
i
i-
-
-
-
lies (according to deve
lies (according to deve
lies (according to deve
lies (according to devel
l
l
l-
-
-
-
oper actions in CC Part 3)
oper actions in CC Part 3)
oper actions in CC Part 3)
oper actions in CC Part 3)
depth of testing analysis
Table
Table
Table
Table 7
7
7
7:
:
:
: List of documents describing the measures regarding the assurance requirements
List of documents describing the measures regarding the assurance requirements
List of documents describing the measures regarding the assurance requirements
List of documents describing the measures regarding the assurance requirements
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7 PP Claims
This Security Target claims conformance to the following protection profile:
- Protection Profile, Smartcard Integrated Circuit; Common Criteria for Information
Technology Security Evaluation; Version 2.0, September 1998, registered at the French
Certification Body under number PP/9806, [6]
The short term for this protection profile used in this document is PP/9806.
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8 Rationale
The chapter is divided into the following sections: “Security Objectives Rationale”, “Security Re-
quirements Rationale”, “TOE Summary Specification Rationale” ,”PP Claims Rationale”.
8.1 Security Objectives Rationale
The security objectives rationale in section 7.2 of the PP/9806 shows, that the threats and as-
sumptions defined in the protection profile are addressed effectively by the security objectives
defined in the PP.
This section deals with the additional items defined in this Security Target.
8.1.1 Threats and objectives
No additional threats are defined in this Security Target. The following discussion shows, how
the objectives address the threats defined in the PP.
SO1 “Mode Control” controls the possibility to switch between Test Mode and User Mode. By
allowing production testing in phase 3 it supports to check the correct operation of the security
functions, thereby supporting O.OPERATE and O.FLAW. By this SO1 addresses in fact all
threats against the TOE (because every attack may be easier in case of incorrect function of parts
of security functionality).
On the other hand it prevents use of test functions in phases 4 to 7 thereby preventing attacks
trying to disclose or modify software, data or design information by the use of test functions. In
addition the mode control ensures the activation of the security functions in the User Mode of
the TOE.
Therefore it addresses (at least) the threats: T.DIS_SOFT, T.DIS_DSOFT, T.DIS_DESIGN,
T.DIS_TEST, T.MOD_SOFT, T.MOD_DSOFT, T.MOD_DESIGN as well as
T.T_SAMPLE and T.T_PRODUCT in the case of unauthorised use.
SO2 “Operating Conditions Control” supports the continuous correct operation of security
functions. When the correct operation cannot be supported because the operation conditions
exceed or fall below the defined threshold the TOE goes into a secure state performing an internal
reset.
Therefore it addresses the threats: T.DIS_SOFT, T.DIS_DSOFT, T.MOD_SOFT,
T.MOD_DSOFT and T.T_SAMPLE, T.T_PRODUCT in the case of unauthorised use.
SO3 “Tamper Proof” supports to prevent disclosure and modification of software, data and de-
sign information thereby addressing (at least) T.DIS_SOFT, T.DIS_DSOFT, T.DIS_DESIGN,
T.DIS_TEST, T.MOD_SOFT, T.MOD_DSOFT, T.MOD_DESIGN as well as
T.T_SAMPLE and T.T_PRODUCT in the case of unauthorised use.
SO4 “Non-existence of Information Leakage ” prevents disclosure of secret data while being
processed by the TOE. Thereby it addresses T.DIS_SOFT and T.DIS_DSOFT and in addition
T.MOD_SOFT, T.MOD_DSOFT and T.MOD_DESIGN regarding the aspect of flaws in the
design.
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SO5 “Cryptographic support” provide good random numbers and hardware DEA calculation.
This helps the embedded software to generate good cryptographic keys and to use DEA for data
confidentiality. Thereby it addresses T.DIS_SOFT and T.DIS_DSOFT.
Note: The threat cloning (T.CLON) of the functional behaviour requires to (i) development of
a functional equivalent of the Smartcard Embedded Software or disclosure of the Smart-
card Embedded Software, (ii) disclose, interpret and employ the secret User Data stored
in the TOE, and (iii) develop and build a functional equivalent of the smartcard using the
input from the previous steps. Therefore this is a combination of T.DIS_SOFT,
T.DIS_DESIGN and T.MOD_SOFT.
In addition the threat T.DIS_SOFT is defined in the PP as follows:
“Unauthorized disclosure of Smartcard Embedded Software and data such as access con-
trol, authentication system, data protection system, memory partitioning, cryptographic
programs.”
Because this threat covers data processed by the Smartcard Embedded Software this also
includes end-user data. The objectives SO4 and SO5 are provided to counter this threat.
The preceding discussion shows that the additional objectives defined in this Security Target in-
tegrate with those of the PP to address the threats effectively.
8.1.2 Assumptions and objectives
The additional assumption A.SOFT_FUNC (see section 3.3) is addressed by the objectives
O.SOFT_MECH and O.DEV_TOOLS. The guidance documentation will contain descriptions,
how the embedded software shall check the integrity of user data and that it shall react adequately
to loss of integrity. It will also describe how the software can determine that a reset was caused by
the sensors and can therefore react correctly. O.SOFT_MECH ensures that the embedded soft-
ware developer uses this information adequately and O.DEV_TOOLS supports the correctness of
this implementation.
The additional assumption A.SCRAP_MARKED is addressed by the additional objective
OE.SCRAP_DEFECT defined in section 4.2. Obviously the assumption is fulfilled if the same
holds for the objective.
8.2 Security Requirements Rationale
8.2.1 Security Functional Requirements for the TOE
The section 7.3 of the PP/9806 shows that the security requirements defined in the PP are suit-
able to meet the security objectives of the TOE defined in the PP. The SFRs stated in section
5.1.1.2 of this Security Target are taken from the PP and suitable operations are described for this
SFRs. Obviously the reasoning given in the PP isn’t affected by these operations. Therefore it
holds unchanged.
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The additional security objectives defined in section 4.1 are met by the SFRs defined in this Tar-
get in the following way:
SO1 “Mode Control”: The Test Mode/ User Mode Security Policy (see the policy definitions in
5.1.1.1) is realised by the SFRs connected with Identification/Authentication/Attribute Manage-
ment/Access control (FMT_MOF.1, FIA_UAU.2, FIA_UID.2, FIA_ATD.1 in section 5.1.1.2,
FMT_MSA.1, FMT_SMR.1, FMT_MSA.3, FDP_ACC.2, FDP_ACF.1, FDP_IFC.1,
FDP_IFF.1 in section 5.1.1.3). Testing of the TOE in phase 3 in Test Mode is realised by
FPT_TST.1 and FDP_SDI.1 (see section 5.1.1.2).
SO2 “Operating Conditions Control”: This is realised by FAU_SAA.1 and FPT_PHP.2 (section
5.1.1.3). Regarding FMT_MOF.1 only an authorised user is allowed to disable the sensors.
SO3 “Tamper Proof”: SFRs FDP_ACC.2 and FDP_ACF.1 define the enforcement of the Tam-
per Protection Security Policy (see section 5.1.1.1), which describes this objective. FPT_PHP.3
also adds to this objective.
SO4 “Non-existence of Information Leakage”: SFR FPR_UNO.1 defines the impossibility of
DPA and Timing attacks.
SO5 “Cryptographic support”: This is defined by the additional SFRs FCS_RND.1 and
FCS_COP.1 (see section 5.1.1.4).
Note that the requirement FCS_RND.1 was not taken from CC, part 2 since no requirements on
the quality of random number generators exist in the CC, part 2 at present.
The refinements added to the SFRs describe in detail how the SFRs support the objectives. Note
that the Security policies derived from the objectives in section 5.1.1.1 are heavily used in all de-
scriptions. The fact that all SFRs work together to realise these policies gives additional assurance
that they build a mutually supportive whole.
8.2.2 Security Functional Requirements Dependencies
The discussion of dependencies given in the PP/9806, section 7.3.2 remains valid for all SFRs
already contained in the PP.
For the SFR FAU_GEN.1 the following additional explanation is given:
The TOE ensures a secure state and enforces a reset when the events (1) to (6) defined in the Se-
curity Functional Requirement FAU_SAA.1 occur. Therefore the TOE cannot audit these events.
Nether the less the TOE provides a flag that is used to indicate whether it is a normal reset or a
reset enforced by an event that indicate a potential violation. In addition the event (7) defined in
the Security Functional Requirement FAU_SAA.1 is indicated by a separate flag. In addition the
dependency of FAU_GEN.1 (FPT_STM.1 Reliable time stamps) cannot be fulfilled because state
of the art smartcard ICs do not include a internal clock.
In addition the extra SFRs are discussed here.
The SFR FCS_RND.1 defines no dependencies.
FCS_COP.1 defines the following dependencies:
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- [FDP_ITC.1 Import of user data without security attributes or FCS_CKM.1 Crypto-
graphic key generation],
- FCS_CKM.4 Cryptographic key destruction,
- FMT_MSA.2 Secure security attributes.
These dependency requirements all address the appropriate management of cryptographic keys
used by the specified cryptographic function. All requirements concerning key management shall
be fulfilled by the environment according to the discussion in 5.2.2.
It was decided not to include the functional requirements [FDP_ITC.1 or FCS_CKM.1],
FCS_CKM.4 and FMT_MSA.2 explicitly as security functional requirements for the IT envi-
ronment because this would mean a restriction for the realisation of the smart card software,
which is not justifiable. The possibility was seen that special smart card applications may be de-
signed that are able to resolve the dependencies without use of all the explicit functional require-
ments (for example by moving some of the functional responsibilities to organisational measures
outside of the smart card). So the more abstract general requirement discussed in 5.2.2 were cho-
sen to give the developers of the smart card software the freedom to choose how to fulfil them.
The same argument holds for further indirect dependencies of FCS_COP.1.1, which exist ac-
cording to CC Part 2 [2]: FDP_ACC.1, FDP_IFC.1, FDP_ACF.1, FDP_IFF.1, FMT_MSA.3,
FCS_CKM.2, FMT_MSA.1, FMT_SMR.1, FIA_UID.1 and ADV_SPM.1 (Note that many of
these requirements appear in this Security Target, but not with respect to the cryptographic key
management for the DEA coprocessor.).
8.2.3 Strength of function level rationale
The reasoning given for the level “high” already in the PP is also valid for this Security Target.
8.2.4 Security assurance requirements rationale
The assurance level EAL5 was chosen in order to meet high assurance expectations as for example
required by the German Digital Signature Act.
The augmentation with the requirements ALC_DVS.2, AVA_VLA.4 and AVA_MSU.3 was cho-
sen to additionally support this. In particular it is expected that attackers with high attack poten-
tial will try to attack high-end digital signature applications. Similar reasoning holds for electronic
payment systems, where highly skilled hackers might try to compromise the system. These con-
siderations show that these high assurance requirements are adequate.
The assurance components in an EAL level are chosen in a way that they build a mutually sup-
portive and complete set of components. The requirements chosen for augmentation do not add
any dependencies, which are not already fulfilled for the corresponding requirements contained in
EAL5. Therefore, these components add additional assurance to EAL5 but the mutual support of
the requirements is still guaranteed.
8.2.5 Security Requirements are mutually supportive and internally consistent
The discussions of SFRs and assurance components in the preceding sections has shown that
mutual support and consistency are given for both groups of requirements. The arguments given
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for the fact that the assurance components are adequate for the functionality of the TOE also
shows that the SFRs and assurance requirements support each other and that there are no incon-
sistencies between these groups.
8.3 TOE Summary Specification Rationale
8.3.1 TOE security functions
In this section a justification is given, why the TOE Security Functions defined in section TOE
Security Functions realise the SFRs defined in sections 5.1.1.2, 5.1.1.3 and 5.1.1.4. This justifi-
cation can be given as a relatively short mapping here, because the main justification is already
contained in the refinements given for the SFRs: A comparison of the refinements with the de-
scriptions of the security functions then shows that the functions are obviously designed to fulfill
the SFRs.
F.COMP realises the Test Mode/User Mode policies defined in section 5.1.1.1. By this it realises
nearly all functionality of the SFRs connected with Identification/Authentication/Attribute Man-
agement/Access control (FMT_MOF.1, FIA_UAU.2, FIA_UID.2, FIA_ATD.1 in section
5.1.1.2, FMT_MSA.1, FMT_SMR.1, FMT_MSA.3, FDP_ACC.2, FDP_ACF.1 in section
5.1.1.3).
From the preceding list of SFRs only the SFRs FDP_ACC.2, FDP_ACF.1 have the additional
property to define the enforcement of the Tamper Protection Security Policy (see section
5.1.1.1). This property is realised by the physical protection provided by F.PHY. FPT_PHP.3 is
also realised by F.PHY, as the definition of this function shows.
The SFRs FCS_RND.1 and FCS_COP.1 (see section 5.1.1.4) are realised by F.RNG and F.DEA
respectively, because they describe exactly the cryptographic functions Random Number Gen-
erator resp. Triple-DEA as required by the SFRs. The properties required by FPR_UNO.1 are
also provided by F.DEA, because it realises measures against DPA and timing attacks, thereby
providing unobservability. The general physical security measures provided by F.PHY of course
also support the unobservability property.
Testing of the TOE is described by F.TEST, which thereby realises FPT_TST.1 and FDP_SDI.1
(see section 5.1.1.2). The realisation of FPT_TST.1 is obvious, while the realisation of
FDP_SDI.1 is clear, when taking the refinement of this SFR into account, which explicitly refers
to the test functions.
The SFRs FDP_IFC.1 and FDP_IFF.1, which describe the fact that test functions cannot be used
in User Mode to disclose or modify data of the embedded software, are also realised by F.COMP,
since the Test Mode/User Mode control includes this property.
The SFRs FAU_SAA.1, FPT_PHP.2 (section 5.1.1.3) are realised by F.OPC: For FAU_SAA.1
see the part of the description of F.OPC, which explicitly refers to FAU_SAA.1, and FPT_PHP.2
is realised because F.OPC triggers a reset when physical tampering is indicated by the sensors of
the TOE.
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8.3.2 Assurance measures
The assurance measures defined in section 6.2 are considered to fulfil the assurance requirements
of the CC [3]. These measures are required to avert the threats defined in the PP/9806 that can-
not be averted by the TOE itself. Since the assurance requirements listed in the PP/9806 are a
subset for the requirements for the level EAL5 all input deliverables as listed in section 6.2 are
suitable to fulfil the assurance requirements.
8.4 PP Claims Rationale
According to section 7 this Security Target claims conformance to the PP/9806 Protection Pro-
file.
The sections of this document, where threats, objectives and security requirements are defined,
clearly state, which of these items are taken from the Protection Profile and which are added in
this ST. Therefore this is not repeated here. In addition the items added in this Security Target
do not contradict to the items included in the Protection Profile. The operations done for the
SFRs taken from the PP are also clearly indicated.
The assurance level claimed for this target (EAL5+) is shown in section 5.1.2 to include resp. ex-
ceed the requirements claimed by the PP (EAL4+).
These considerations show that the Security Target correctly claims conformance to the PP/9806.
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9 Annexes
9.1 Definition of specific IT security functional requirements
To define the IT security functional requirements of the TOE an additional family (FCS_RND)
of the Class FCS (cryptographic support) is defined here. This class describes the functional re-
quirements for random number generation used for cryptographic purposes.
FCS_RND Generation of random numbers
FCS_RND Generation of random numbers
FCS_RND Generation of random numbers
FCS_RND Generation of random numbers
Family behaviour
Family behaviour
Family behaviour
Family behaviour
This family defines quality requirements for the generation of random
numbers which are intended to be use for cryptographic purposes.
Component levelling
Component levelling
Component levelling
Component levelling
FCS_RND.1 Generation of random numbers requires that random num-
bers meet a defined quality metric.
Management: FCS_RND.1
Management: FCS_RND.1
Management: FCS_RND.1
Management: FCS_RND.1
There are no management activities foreseen.
Audit: FCS_RND.1
Audit: FCS_RND.1
Audit: FCS_RND.1
Audit: FCS_RND.1
There are no actions defined to be auditable.
FCS_RND.1 Quality metric for random numbers
FCS_RND.1 Quality metric for random numbers
FCS_RND.1 Quality metric for random numbers
FCS_RND.1 Quality metric for random numbers
Hierarchical to: No other components.
FCS_RND.1.1 The TSF shall provide a mechanism to generate random numbers that
have an [assignment: a defined quality metric].
Dependencies: No dependencies.
FCS_RND Generation of random numbers
FCS_RND Generation of random numbers
FCS_RND Generation of random numbers
FCS_RND Generation of random numbers 1
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9.2 Abbreviations
IC Integrated Circuit
O Object
OTP One Time Programmable
PP Protection Profile
S Subject
SEF Security Enforcing Function
SF Security function
SFP Security Function Policies
SOF Strength of function
ST Security Target
TOE Target of Evaluation
TSF TOE Security functions
TSP TOE Security Policy
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9.3 Bibliography
[1] Common Criteria for Information Technology Security Evaluation, Part 1: Introduction
and General Model; Version 2.1, August 1999
[2] Common Criteria for Information Technology Security Evaluation, Part 2: Security
Functional Requirements; Version 2.1, August 1999
[3] Common Criteria for Information Technology Security Evaluation, Part 3: Security As-
surance Requirements; Version 2.1, August 1999
[4] Common Methodology for Information Technology Security Evaluation CEM-99/045
Part 2: Evaluation Methodology, Version 1.0, August 1999
[5] Anwendungshinweise und Interpretationen zum Schema, AIS31: Funktionalitätsklassen
und Evaluationsmethodologie für physikalische Zufallszahlengeneratoren, Version 1,
25.09.2001, Bundesamt für Sicherheit in der Informationstechnik
[6] Protection Profile, Smartcard Integrated Circuit; Common Criteria for Information
Technology Security Evaluation; Version 2.0, September 1998, registered at the French
Certification Body under number PP/9806
[7] FIPS PUB 46-3 FEDERAL INFORMATION PROCESSING STANDARDS
PUBLICATION DATA ENCRYPTION STANDARD (DES) Reaffirmed 1999 Octo-
ber 25
[8] ISO/IEC 7816-2:1996 Information technology – Identification cards – Integrated cir-
cuit(s) cards with contacts – Part 2: Dimensions and location of contacts
[9] ISO/IEC 7816-3:1997 Information technology – Identification cards – Integrated cir-
cuit(s) cards with contacts – Part 3: Electronic signals and transmission protocols
[10] Data Sheet, P8WE6017 Secure 8-bit Smart Card Controller, Product Specification,
Philips Semiconductors, Revision 3.3, Document Number: 043133, July 5th
, 2002
[11] Guidance, Delivery and Operation Manual for the P8WE6017V1J, Philips Semiconduc-
tors