Security Target for
IBM z/OS Version 1 Release 13
Version: 9.02
Status: Final
Last Update: 2012-09-09
Classification: Public
Security Target for
IBM z/OS Version 1 Release 13
Trademarks
The following terms are trademarks or registered trademarks of International Business
Machines Corporation in the United States, other countries, or both:
 Advanced Function Presentation
 AFP
 BladeCenter
 DFS
 DFSORT

 IBM
 Infoprint
 MVS
 PR/SM
 Print Services Facility
 Processor Resource/Systems Manager
 RACF
 System z
 VTAM
 z/Architecture
 zEnterprise
 z/OS
 z/VM
 zSeries
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 z10
Java and all Java-based trademarks and logos are trademarks or registered trademarks of
Oracle and/or its affiliates.
UNIX is a registered trademark of The Open Group in the United States, other countries, or
both.
Other company, product, and service names may be trademarks or service marks of others.
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Revision History
Revision Author(s) Date Changes to Previous Revision
9.02 Walter Farrell, IBM,
Helmut Kurth, atsec
2012-09-09 Public version of ST
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Table of Contents
1 Introduction.................................................................................................11
1.1 Security Target Identification......................................................................................11
1.2 TOE Identification........................................................................................................11
1.3 TOE Overview..............................................................................................................11
1.4 TOE Description...........................................................................................................12
1.4.1 Intended Method of Use.........................................................................................................13
1.4.2 Summary of Security Features...............................................................................................15
1.4.2.1 Identification and authentication..............................................................................................................15
1.4.2.2 Discretionary access control.....................................................................................................................16
1.4.2.3 Mandatory access control and support for security labels.......................................................................18
1.4.2.4 Auditing.....................................................................................................................................................19
1.4.2.5 Object reuse functionality.........................................................................................................................19
1.4.2.6 Security management..............................................................................................................................20
1.4.2.7 Communications Security.........................................................................................................................20
1.4.2.8 TSF protection...........................................................................................................................................22
1.4.3 Configurations........................................................................................................................ 22
1.4.3.1 Software configuration..............................................................................................................................22
1.4.3.2 Hardware configuration............................................................................................................................28
1.4.4 Structure................................................................................................................................ 29
2 CC Conformance Claim..................................................................................30
3 Security Problem Definition..........................................................................31
3.1 Introduction.................................................................................................................31
3.2 Threat Environment....................................................................................................31
3.2.1 Assets.................................................................................................................................... 31
3.2.2 Threat agents........................................................................................................................ 31
3.2.3 Threats countered by the TOE...............................................................................................32
3.3 Assumptions................................................................................................................32
3.3.1 Environment of use of the TOE..............................................................................................33
3.3.1.1 Physical.....................................................................................................................................................33
3.3.1.2 Personnel..................................................................................................................................................33
3.3.1.3 Procedural.................................................................................................................................................33
3.3.1.4 Connectivity..............................................................................................................................................33
3.4 Organizational Security Policies..................................................................................33
4 Security Objectives.......................................................................................35
4.1 Objectives for the TOE.................................................................................................35
4.2 Objectives for the Operational Environment................................................................36
4.3 Security Objectives Rationale......................................................................................37
4.3.1 Security Objectives Coverage................................................................................................37
4.3.2 Security Objectives Sufficiency..............................................................................................40
5 Extended Components Definition..................................................................47
5.1 FCS_CKM_EXT.1 Cryptographic key generation with platform support........................47
5.2 FCS_COP_EXT.1 Cryptographic operation with platform support.................................47
6 Security Requirements for the Operational Environment................................49
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6.1 General security requirements for the abstract machine............................................50
6.1.1 Subset access control (FDP_ACC.1(E))...................................................................................50
6.1.2 Security-attribute-based access control (FDP_ACF.1(E)).........................................................50
6.1.3 Static attribute initialization (FMT_MSA.3(E)).........................................................................51
6.2 Security requirements for CPACF................................................................................52
6.2.1 Cryptographic operation (DES) (FCS_COP.1(1E))....................................................................52
6.2.2 Cryptographic operation (AES) (FCS_COP.1(2E))....................................................................52
6.2.3 Cryptographic operation (SHA-1) (FCS_COP.1(3E)).................................................................52
6.2.4 Cryptographic operation (SHA-2) (FCS_COP.1(4E)).................................................................53
6.3 Security requirements for CEX3 in CEX3C mode.........................................................53
6.3.1 Cryptographic operation (RSA) (FCS_COP.1(7E))....................................................................53
6.3.2 Cryptographic key generation (Public/Private Keys) (FCS_CKM.1(2E))....................................54
6.4 Security requirements for CEX3 in CEX3A mode.........................................................54
6.4.1 Cryptographic support operation (FCS_COP.1(6E))................................................................54
6.5 Additional Security requirements for CryptoExpress 3 (CEX3) on z114 and z196 ......54
6.5.1 Cryptographic operation (ECC Digital Signature Generation) (FCS_COP.1(8E)).......................54
6.5.2 Cryptographic operation (ECC Digital Signature Verification) (FCS_COP.1(9E))......................55
6.5.3 Cryptographic key generation (ECDSA Public/Private Keys) (FCS_CKM.1(3E))........................55
7 Security Requirements.................................................................................56
7.1 TOE Security Functional Requirements.......................................................................56
7.1.1 Security audit (FAU)............................................................................................................... 64
7.1.1.1 Audit data generation (FAU_GEN.1)..........................................................................................................64
7.1.1.2 User identity association (FAU_GEN.2).....................................................................................................72
7.1.1.3 Audit review (FAU_SAR.1).........................................................................................................................72
7.1.1.4 Restricted audit review (FAU_SAR.2)........................................................................................................73
7.1.1.5 Selectable audit review (FAU_SAR.3).......................................................................................................73
7.1.1.6 Selective audit (FAU_SEL.1)......................................................................................................................73
7.1.1.7 Protected audit trail storage (FAU_STG.1)................................................................................................73
7.1.1.8 Action in case of possible audit data loss (FAU_STG.3)............................................................................73
7.1.1.9 Prevention of audit data loss (FAU_STG.4)...............................................................................................74
7.1.2 Cryptographic support (FCS)..................................................................................................74
7.1.2.1 Cryptographic key generation: symmetric algorithms (FCS_CKM.1(SYM))..............................................74
7.1.2.2 Cryptographic key generation: RSA (FCS_CKM.1(RSA))...........................................................................75
7.1.2.3 Cryptographic key generation: DSA (FCS_CKM.1(DSA))...........................................................................75
7.1.2.4 Cryptographic key generation with platform support: ECDSA (ECDH) (FCS_CKM_EXT.1(ECDSA))..........76
7.1.2.5 Cryptographic key distribution (FCS_CKM.2(NET))...................................................................................76
7.1.2.6 Cryptographic key destruction (FCS_CKM.4)............................................................................................77
7.1.2.7 Cryptographic operation with platform support: signatures (FCS_COP_EXT.1(SGN))..............................78
7.1.2.8 Cryptographic operation: network (FCS_COP.1(NET))..............................................................................78
7.1.2.9 Cryptographic Operation with platform support (FCS_COP_EXT.1 (CRYPTO-ENC))..................................80
7.1.2.10 Cryptographic Operation with platform support (FCS_COP_EXT.1 (CRYPTO-MD)).................................81
7.1.2.11 Cryptographic Operation with platform support (FCS_COP_EXT.1 (CRYPTO-SGN))...............................82
7.1.2.12 Random number generation (FCS_RNG.1).............................................................................................83
7.1.3 User data protection (FDP).....................................................................................................83
7.1.3.1 Subset access control: persistent objects (FDP_ACC.1(PSO))..................................................................83
7.1.3.2 Subset access control: transient objects (FDP_ACC.1(TSO))....................................................................84
7.1.3.3 Security attribute based access control: MVS (FDP_ACF.1(PSO-MVS))....................................................84
7.1.3.4 Security attribute based access control: UNIX (FDP_ACF.1(PSO-UNIX))...................................................87
7.1.3.5 Security attribute based access control: LDAP (FDP_ACF.1(PSO-LDAP))..................................................89
7.1.3.6 Security attribute based access control: UNIX IPC (FDP_ACF.1(TSO)).....................................................92
7.1.3.7 Export of user data without security attributes (FDP_ETC.1 (Labeled Security Mode only))...................93
7.1.3.8 Export of user data with security attributes (FDP_ETC.2(LS) (Labeled Security Mode only))..................93
7.1.3.9 Complete information flow control: labeled security (FDP_IFC.2(LS) (Labeled Security Mode only))......94
7.1.3.10 Complete information flow control: network (FDP_IFC.2(NI)).................................................................94
7.1.3.11 Simple security attributes (FDP_IFF.1(NI))..............................................................................................95
7.1.3.12 Hierarchical security attributes (FDP_IFF.2(LS) (Labeled Security Mode only)).....................................96
7.1.3.13 Import of user data without security attributes (FDP_ITC.1(LS) (Labeled Security Mode only))............97
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7.1.3.14 Import of user data with security attributes (FDP_ITC.2).......................................................................98
7.1.3.15 Import of user data with security attributes: labeled security (FDP_ITC.2(LS) (Labeled Security Mode
only))......................................................................................................................................................................98
7.1.3.16 Full residual information protection (FDP_RIP.2)....................................................................................99
7.1.3.17 Full residual information protection of resources (FDP_RIP.3)...............................................................99
7.1.4 Identification and authentication (FIA)...................................................................................99
7.1.4.1 Authentication failure handling (FIA_AFL.1).............................................................................................99
7.1.4.2 User attribute definition: human users (FIA_ATD.1(HU))..........................................................................99
7.1.4.3 User attribute definition: technical users (FIA_ATD.1(TU)).....................................................................100
7.1.4.4 User attribute definition: EIA (FIA_ATD.1(EIA)).......................................................................................101
7.1.4.5 User attribute definition: labeled security (FIA_ATD.1(LS) (Labeled Security Mode only))....................101
7.1.4.6 Verification of secrets (FIA_SOS.1).........................................................................................................101
7.1.4.7 Timing of authentication (FIA_UAU.1).....................................................................................................101
7.1.4.8 Multiple authentication mechanisms (FIA_UAU.5)..................................................................................102
7.1.4.9 Protected authentication feedback (FIA_UAU.7).....................................................................................103
7.1.4.10 Authentication policy decisions (FIA_UAU.8(EIA))................................................................................103
7.1.4.11 Timing of identification (FIA_UID.1)......................................................................................................104
7.1.4.12 Identification policy decisions (FIA_UID.3(EIA))....................................................................................104
7.1.4.13 User-subject binding (FIA_USB.1(LS) (Labeled Security Mode only))...................................................105
7.1.4.14 Enhanced user-subject binding (FIA_USB.2).........................................................................................105
7.1.5 Security management (FMT)................................................................................................107
7.1.5.1 Management of object security attributes: persistent objects (FMT_MSA.1(PSO))................................107
7.1.5.2 Management of object security attributes: transient objects (FMT_MSA.1(TSO))..................................107
7.1.5.3 Management of object security attributes: labeled security (FMT_MSA.1(LS) (Labeled Security Mode
only))....................................................................................................................................................................108
7.1.5.4 Static attribute initialization: persistent objects (FMT_MSA.3(PSO))......................................................108
7.1.5.5 Static attribute initialization: transient objects (FMT_MSA.3(TSO))........................................................108
7.1.5.6 Static attribute initialization: network (FMT_MSA.3(NI)).........................................................................108
7.1.5.7 Static attribute initialization: labeled security (FMT_MSA.3(LS) (Labeled Security Mode only))............109
7.1.5.8 Security attribute value inheritance: persistent objects (FMT_MSA.4(PSO))..........................................109
7.1.5.9 Management of TSF data: audit events (FMT_MTD.1(AE)).....................................................................109
7.1.5.10 Management of TSF data: audit storage (FMT_MTD.1(AS))..................................................................109
7.1.5.11 Management of TSF data: audit trail threshold (FMT_MTD.1(AT)).......................................................110
7.1.5.12 Management of TSF data: audit storage failure (FMT_MTD.1(AF)).......................................................110
7.1.5.13 Management of TSF data: network filters (FMT_MTD.1(NI)).................................................................110
7.1.5.14 Management of TSF data: IPSec (FMT_MTD.1(NI2)).............................................................................111
7.1.5.15 Management of TSF data: authentication threshold (FMT_MTD.1(IAT))...............................................111
7.1.5.16 Management of TSF data: account re-enablement (FMT_MTD.1(IAF)).................................................111
7.1.5.17 Management of TSF data: user security attributes (FMT_MTD.1(IAU))................................................112
7.1.5.18 Management of TSF data: authentication data (FMT_MTD.1(IAU-AUTH))............................................112
7.1.5.19 Management of TSF data: EIA (FMT_MTD.1(EIA)).................................................................................113
7.1.5.20 Management of TSF data: key import (FMT_MTD.1(CRYPTO1))...........................................................113
7.1.5.21 Management of TSF data: digital certificates (FMT_MTD.1(CRYPTO2))................................................114
7.1.5.22 Management of TSF data: additional configuration (FMT_MTD.1(ADD))..............................................114
7.1.5.23 Revocation: objects (FMT_REV.1(OBJ)).................................................................................................114
7.1.5.24 Revocation: users (FMT_REV.1(USR))...................................................................................................115
7.1.5.25 Specification of Management Functions (FMT_SMF.1).........................................................................115
7.1.5.26 Security roles (FMT_SMR.1)..................................................................................................................115
7.1.6 Protection of the TSF (FPT)...................................................................................................117
7.1.6.1 Reliable time stamps (FPT_STM.1)..........................................................................................................117
7.1.6.2 Inter-TSF basic TSF data consistency (FPT_TDC.1).................................................................................117
7.1.6.3 Inter-TSF basic TSF data consistency: labeled security (FPT_TDC.1(LS) (Labeled Security Mode only))
.............................................................................................................................................................................117
7.1.7 TOE access (FTA)................................................................................................................. 117
7.1.7.1 TSF-initiated session locking (FTA_SSL.1)...............................................................................................117
7.1.7.2 User-initiated locking (FTA_SSL.2)..........................................................................................................118
7.1.8 Trusted path/channels (FTP)................................................................................................118
7.1.8.1 Inter-TSF trusted channel (FTP_ITC.1)....................................................................................................118
7.2 Security Functional Requirements Rationale.............................................................119
7.2.1 Security Requirements Coverage.........................................................................................119
7.2.2 Security Requirements Sufficiency.......................................................................................124
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7.2.3 Security Requirements Dependency Analysis......................................................................128
7.2.4 TSF Rationale....................................................................................................................... 138
7.2.5 Mutual support of the security functions..............................................................................147
7.3 Security Assurance Requirements.............................................................................148
7.3.1 Security Target evaluation (ASE)..........................................................................................149
7.3.1.1 Conformance claims (ASE_CCL.1(CCR)).................................................................................................149
7.4 Security Assurance Requirements Rationale.............................................................149
8 TOE Summary Specification.........................................................................149
8.1 TOE Security Functionality........................................................................................149
8.1.1 Overview of the TOE architecture........................................................................................149
8.1.1.1 Main trusted subsystems of the evaluated configuration......................................................................151
8.1.2 Identification and Authentication.........................................................................................153
8.1.2.1 Authentication function..........................................................................................................................153
8.1.2.2 RACF Passwords and Password Phrases.................................................................................................157
8.1.2.3 RACF PassTickets....................................................................................................................................161
8.1.2.4 Authentication via Client Digital Certificates..........................................................................................164
8.1.2.5 Authentication via Public/Private Key (SSH)...........................................................................................166
8.1.2.6 Authentication via Kerberos...................................................................................................................167
8.1.2.7 Started procedures.................................................................................................................................168
8.1.2.8 Authentication by trusted servers..........................................................................................................169
8.1.2.9 Authentication Method Summary...........................................................................................................172
8.1.2.10 Handling of Groups During Authentication...........................................................................................173
8.1.2.11 Authentication-related differences between z/OS UNIX and typical non-z/OS UNIX systems..............174
8.1.2.12 Assertion of User Identity.....................................................................................................................177
8.1.3 Discretionary Access Control................................................................................................178
8.1.3.1 Access control principles........................................................................................................................178
8.1.3.2 Protected resources................................................................................................................................180
8.1.3.3 Discretionary Access Control..................................................................................................................204
8.1.3.4 DAC for MVS resources...........................................................................................................................205
8.1.3.5 DAC for UNIX objects..............................................................................................................................210
8.1.3.6 DAC for LDAP LDBM objects....................................................................................................................212
8.1.3.7 Access Control Considerations for the ISPF Client Gateway...................................................................215
8.1.4 Communication security......................................................................................................216
8.1.4.1 Communications Server..........................................................................................................................216
8.1.4.2 System SSL.............................................................................................................................................221
8.1.4.3 Network Authentication Service.............................................................................................................221
8.1.4.4 NFS Client and Server.............................................................................................................................221
8.1.4.5 IBM Ported Tools for z/OS (OpenSSH).....................................................................................................222
8.1.5 Management........................................................................................................................ 222
8.1.5.1 User and group management.................................................................................................................222
8.1.5.2 Resource management...........................................................................................................................265
8.1.5.3 RACF configuration and management....................................................................................................273
8.1.5.4 Network configuration and management...............................................................................................299
8.1.5.5 PKI Services............................................................................................................................................302
8.1.5.6 Security Management for System Logger Log Streams.........................................................................306
8.1.6 Auditing............................................................................................................................... 307
8.1.6.1 Generation of audit records....................................................................................................................307
8.1.6.2 Protection of the audit trail.....................................................................................................................309
8.1.6.3 Using MVS Data Sets for SMF.................................................................................................................309
8.1.6.4 Using a System Log Stream for SMF.......................................................................................................310
8.1.6.5 Audit configuration and management....................................................................................................310
8.1.7 Object reuse........................................................................................................................ 310
8.1.8 TOE self-protection..............................................................................................................311
8.1.8.1 Supporting mechanisms of the abstract machine..................................................................................311
8.1.8.2 Supervisor state routines in z/OS...........................................................................................................313
8.1.8.3 Authorized programs..............................................................................................................................313
8.1.8.4 Program Signing and Verification...........................................................................................................315
8.1.9 Session Locking...................................................................................................................318
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8.1.10 Implementation of cryptographic functions........................................................................318
8.1.10.1 Cryptographic Functions for Application Use.......................................................................................318
8.1.10.2 FIPS 140-2.............................................................................................................................................319
8.1.10.3 CPACF....................................................................................................................................................321
8.1.10.4 CEX3 in CEX3C mode............................................................................................................................321
8.1.10.5 CEX3 in CEX3A mode............................................................................................................................321
8.1.11 Self-test functions.............................................................................................................. 322
8.2 TOE Assurance Measures..........................................................................................322
9 Abbreviations, Terminology and References................................................326
9.1 Abbreviations............................................................................................................326
9.2 Terminology..............................................................................................................327
9.3 References................................................................................................................329
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List of Tables
Table 1: Mapping of security objectives to threats and policies............................................39
Table 2: Mapping of security objectives for the Operational Environment to assumptions,
threats and policies...............................................................................................................40
Table 3: Sufficiency of objectives countering threats............................................................42
Table 4: Sufficiency of objectives holding assumptions.........................................................45
Table 5: Sufficiency of objectives enforcing Organizational Security Policies........................46
Table 6: Security functional requirements for the TOE..........................................................64
Table 7: Auditable Events......................................................................................................72
Table 8: Mapping of security functional requirements to security objectives......................124
Table 9: Security objectives for the TOE rationale...............................................................128
Table 10: TOE SFR dependency analysis.............................................................................138
Table 11: Mapping security functional requirements to security functions..........................147
Table 12: Security assurance requirements for the TOE......................................................149
Table 13: General Resource Classes for DB2.......................................................................185
Table 14: General Resource Classes for EIM........................................................................185
Table 15: General Resource Classes for ICSF......................................................................186
Table 16: General Resource Classes for PSF........................................................................186
Table 17: General Resource Classes for Kerberos...............................................................186
Table 18: General Resource Classes for DFSMS..................................................................186
Table 19: General Resource Classes for TSO.......................................................................186
Table 20: General Resource Classes for z/OS Unix..............................................................187
Table 21: Assurance measures meeting the TOE security assurance requirements............325
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1 Introduction
1.1 Security Target Identification
Title: Security Target for IBM z/OS Version 1 Release 13
Version: 9.02
Status: Final
Date: 2012-09-09
Sponsor: IBM Corporation
Developer: IBM Corporation
Certification
ID:
BSI-DSZ-CC-0788
Keywords: access control, discretionary access control, general-purpose operating
system, information protection, security labels, mandatory access control,
security, UNIX®
1.2 TOE Identification
The TOE is IBM z/OS Version 1 Release 13.
1.3 TOE Overview
This Security Target (ST) documents the security characteristics of the IBM z/OS Version 1
Release 13 operating system with the additional required licensed programs (see section
Software configuration of this ST) configured in a secure manner as described in z/OS
Planning for Multilevel Security and the Common Criteria ([PMLS]).
IBM z/OS, a highly-secure, robust, scalable, high-performance enterprise operating system
on which to build and deploy mission-critical applications, provides a comprehensive and
diverse application execution environment. IBM z/OS is the flagship operating system for IBM
System z™ mainframe computers, empowering the use of their most advanced features,
such as the 64-bit z/Architecture™. It delivers the highest qualities of service for enterprise
transactions and data and extends these qualities to new applications using the latest
software technologies. IBM z/OS serves as the heart of customers’ IT infrastructures, helping
to integrate their information strategy and business strategy.
IBM z/OS can be used on a single IBM System z mainframe computer, or several systems or
logical partitions running the evaluated version of IBM z/OS can be connected to form a
loosely-coupled complex of systems called a sysplex.
IBM z/OS provides such software technologies as Enterprise Java™ Beans, eXtensible Markup
Language (XML), HyperText Markup Language (HTML), Unicode and distributed Internet
Protocol (IP) networking. z/OS UNIX System Services allows customers to develop and run
UNIX programs on z/OS and exploit the reliability and scalability of the System z processors.
z/OS also incorporates cryptographic services, distributed print services, workload
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management, storage management, parallel sysplex availability, and automation
capabilities. Not all of these functions have been analyzed in this evaluation; see section
Software configuration for the software configuration of z/OS used in this evaluation. The
security functions subject to this evaluation are described in chapter 8 of this document.
With such outstanding security features as multilevel security support, IBM z/OS meets all of
the requirements of the Operating System Protection Profile base [OSPP], as well as its
extended packages for extended identification and authentication [OSPP-EIA], and labeled
security [OSPP-LS].
IBM z/OS provides identification and authentication of users using different authentication
mechanisms, both discretionary and mandatory access control to a large number of different
objects, a configurable audit functionality, protection of communication services,
sophisticated security management functions, preparation of objects for reuse and
functionality used internally to protect z/OS from interference and tampering by untrusted
users or subjects.
1.4 TOE Description
The Target of Evaluation (TOE) is the z/OS operating system with the software components
as described in section Software configuration. z/OS is a general-purpose, multi-user, multi-
tasking operating system for enterprise computing systems. Multiple users can use z/OS
simultaneously to perform a variety of functions that require controlled, shared access to the
information stored on the system.
In this ST, the TOE is seen as one instance of z/OS running on an abstract machine as the
sole operating system and exercising full control over this abstract machine. This abstract
machine can be provided by one of the following:
 a logical partition provided by a certified version of PR/SM on an IBM System z™
processor (IBM System z10™ Business Class, IBM System z10™ Enterprise Class,
zEnterprise 114, or zEnterprise 196).
 a certified version of z/VM® executing in a logical partition provided by PR/SM on one
of the above-listed System z™ processors.
If the configuration includes a zEnterprise BladeCenter Extension (zBX), the operating
systems running in the zBX are not part of the TOE. They are external systems, connected to
z/OS only via the built-in TCP/IP networking facilities included in the zEnterprise System and
zBX.
The abstract machine itself is not part of the TOE, rather, it belongs to the TOE environment.
Nevertheless the correctness of separation and memory protection mechanisms
implemented in the abstract machine is analyzed as part of the evaluation since those
functions are crucial for the security of the TOE.
The TOE environment, as part of the System z processor, also includes specific hardware
functions that provide support for the cryptographic operations involved in communications
security and for the digital signature operations involved with X.509v3 digital certificates.
Multiple instances of the TOE may be connected in a basic sysplex or in a parallel sysplex
with the instances sharing their RACF® database.
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The platforms selected for the evaluation consist of IBM products that are available when
the evaluation has been completed and will remain available for a substantial period of time
afterward.
The individual TOEs can be run alone or within a network as a set of cooperating hosts,
operating under and implementing the same set of security policies.
Transmission Control Protocol/Internet Protocol (TCP/IP) network services, connections, and
communication that occur outside of a sysplex are restricted to one security label; that is,
each system regards its peers as single-label hosts. Other network communication is
disallowed, with the exception of the Job Entry System 2 (JES2) Network Job Entry (NJE)
protocol.
Most of the TOE security functions (TSF) are provided by the z/OS operating system Base
Control Program (BCP) and the Resource Access Control Facility (RACF), a z/OS component
that is used by different services as the central instance for identification and authentication
and for access control decisions. z/OS comes with management functions that allow
configuring of the TOE security functions to tailor them to the customer’s needs.
Some elements have been included in the TOE that do not provide security functions. These
elements run in authorized mode, so they could compromise the TOE if they do not behave
properly. Because these elements are essential for the operation of many customer
environments, the inclusion of these elements subjects them to the process of scrutiny
during the evaluation and ensures that they may be used by customers without affecting the
TOE’s security status.
In its evaluated configuration, the TOE allows two modes of operation: a standard mode
meeting all requirements of the Operating System Protection Profile base [OSPP] and its
extended package for Extended Identification and Authentication [OSPP-EIA], and a more
restrictive mode called Labeled Security Mode, which additionally meets all requirements of
the OSPP extended package for Labeled Security [OSPP-LS]. In both modes, the same
software elements are used. The two modes have different RACF settings with respect to the
use of security labels. All other configuration parameters are identical in the two modes.
Throughout this Security Target, all claims that are valid for the Labeled Security Mode only
are marked accordingly. Any claim not marked for Labeled Security Mode applies to both
modes.
1.4.1 Intended Method of Use
z/OS provides a general computing environment that allows users to gain controlled access
to its resources in different ways:
 online interaction with users through Time Sharing Option Extensions (TSO/E) or z/OS
UNIX System Services
 batch processing (JES2)
 services provided by started procedures or tasks
 daemons and servers utilizing z/OS UNIX System Services that provide similar
functions as started procedures or tasks but based on UNIX interfaces
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These services can be accessed by users local to the computer systems or accessing the
systems via network services supported by the evaluated configuration.
All users of the TOE are assigned a unique user identifier (user ID). This user ID, which is
used as the basis for access control decisions and for accountability, associates the user
with a set of security attributes. In most cases the TOE authenticates the claimed identity of
a user before allowing this user to perform any further security-relevant actions. Exceptions
to this authentication policy include:
i. Pre-specified identities:
a. The authorized administrator can specify an identity to be used by server or
daemon processes or system address spaces, which may be started either
automatically or via system operator commands;
b. The authorized administrator may configure a trusted HTTP server to access
selected data under a specified identity, rather than the identity of the end
user making the request. The HTTP server may optionally authenticate the
user in this case, or may serve the data to anyone asking for it, if the
administrator has determined that such anonymous access is appropriate.
ii. Users are allowed to execute programs that accept network connections on ports the
user has access to. In this case the untrusted program has no knowledge about the
external "user" and cannot perform authentication. The program executes with the
rights of the z/OS user that started it, and any data access occurs using this user’s
authenticated identity.
The TOE provides mechanisms for both mandatory and discretionary access control. This
Security Target describes two modes of operation: one with discretionary access control only
and one with both discretionary and mandatory access control where the mandatory access
control is fully enabled for all subjects and objects . In commercial environments it is often
useful to activate only part of the mandatory access control functions required in this
Security Target . While such a mode may be useful for specific environments and the
functions used have been evaluated, the claims about information flow control made in this
Security Target for the Labeled Security Mode may not hold completely when only part of
the mandatory access control functions are configured.
All TOE resources are under the control of the TOE. The TOE mediates the access of subjects
to TOE-protected objects. Subjects in the TOE are called tasks. Tasks are the active entities
that can act on the user’s behalf. Data is stored in named objects. The TOE can associate a
set of security attributes with each named resource, which includes the description of the
access rights to that object and (in Labeled Security Mode) a security label.
Objects are owned by users, who are assumed to be capable of assigning discretionary
access rights to their objects in accordance with the organizational security policies.
Ownership of named objects can be transferred under the control of the access control
policy. In Labeled Security Mode, security labels are assigned by the TOE, either
automatically upon creation of the object or by the trusted system administrator. The
security attributes of users, data objects, and objects through which the information is
passed are used to determine if information may flow through the system as requested by a
user.
Apart from normal users, z/OS recognizes administrative users with special authorizations.
These users are trusted to perform system administration and maintenance tasks, which
includes configuration of the security policy enforced by the z/OS system and attributes
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related to it. Authorizations can be delegated to other administrative users by updating their
security attributes.
The TOE also recognizes the role of an auditor, who uses the auditing system provided by
z/OS to monitor the system usage according to the organizational security policies.
The TOE is intended to operate in a networked environment with other instantiations of the
TOE as well as other well-behaved client systems operating within the same management
domain. All of those systems need to be configured in accordance with a defined common
security policy.
1.4.2 Summary of Security Features
The primary security features of the product are:
 identification and authentication
 discretionary access control
 in Labeled Security Mode: mandatory access control and support for security labels
(Note that security labels can be used in standard mode, too, if allowed by the
security administrator.)
 auditing
 object reuse
 security management
 secure communication
 TSF protection
These primary security features are supported by domain separation and reference
mediation, which ensure that the features are always invoked and cannot be bypassed.
1.4.2.1 Identification and authentication
z/OS provides identification and authentication of users by the means of
 an alphanumeric RACF user ID and a system-encrypted password or (for applications
that support it) password phrase.
 an alphanumeric RACF user ID and a PassTicket, which is a cryptographically-
generated password substitute encompassing the user ID, the requested application
name, and the current date/time.
 an X.509v3 digital certificate presented to a server application that uses System SSL
or TCP/IP Application Transparent TLS (AT-TLS) to provide TLS- or SSLv3-based client
authentication, and then “mapped” (using TOE functions) by that server application
or by AT-TLS to a RACF user ID.
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 a Kerberos™ v5 ticket presented to a server application that supports the Kerberos
mechanism, and then mapped by that application through the TOE-provided GSS-API
programming services or alternate functions that are also provided by the TOE
(specifically the R_ticketServ, and R_GenSec services). These functions enable the
application server to validate the Kerberos ticket, and thus the authentication of the
principal. The application server then translates (or maps) the Kerberos principal
(using the TOE provided function of R_userMap) to a RACF user ID.
 an LDAP LDBM bind DN (which is mapped to a RACF user ID by information in the
LDAP directory) or an LDAP ICTX or SDBM bind DN (which contains a RACF user ID)
together with a RACF password or password phrase. The bind processing then passes
the derived RACF user ID, and the password/phrase, to RACF to complete the
authentication process.
 a digital certificates presented to LDAP over SSL/TLS (LDAP SASL bind with EXTERNAL
verification) which must map to a RACF USER ID.
In the evaluated configuration, all human users are assigned a unique user ID. This user ID
supports individual accountability. The TOE security functions authenticate the claimed
identity of the user by verifying the password/phrase (or other mechanism, as listed above)
before allowing the user to perform any actions that require TSF mediation, other than
actions that aid an authorized user in gaining access to the TOE.
In some cases of external access to the system, such as the HTTP server, or LDAP server, an
installation may decide to define a user ID that is used for access checking of selected
resources for users that have not been authenticated. This allows an installation to define
resources unauthenticated users may access using that server via an appropriate client
program. Users may still authenticate to the server using their user ID and password/phrase
(or other authentication mechanism as above) to access additional resources they have
been assigned access to.
The required password quality can be tailored to the installation’s policies using various
parameters. When creating users, administrators are required to choose an initial password
and optionally a password phrase, that must usually be changed by the user during the
initial logon that uses the password/phrase.
1.4.2.2 Discretionary access control
z/OS supports access controls that are capable of enforcing access limitations on individual
users and data objects. Discretionary access control (DAC) allows individual users to specify
how such resources as direct access storage devices (DASDs), DASD and tape data sets, and
tape volumes that are under their control are to be shared.
RACF makes access control decisions based on the user’s identity, security attributes, group
authorities, and the access authority specified with respect to the resource profile.
z/OS provides three DAC mechanisms:
i. The z/OS standard DAC mechanism is used for most traditional (non-UNIX) protected
objects.
ii. The z/OS UNIX DAC mechanism is used for z/OS UNIX objects (files, directories, etc.)
iii. The z/OS LDAP LDBM DAC mechanism is used to protect LDAP objects in the LDAP
LDBM back-end data store. [Note: z/OS LDAP also supports the CDBM back-end.
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Statements in this Security Target about LDBM, including how DAC mechanisms
work, apply to both LDBM and CDBM. However, CDBM can hold administrative
policies for the LDAP server, and LDAP applies additional,CDBM-specific access
control policies to the CDBM directory information tree containing those policies
when accessed by a member of the LDAP administrative group, as described later in
the LDAP Management section.]
z/OS standard DAC mechanism
Access types that can be granted are NONE, EXECUTE, READ, UPDATE, CONTROL, and
ALTER, which form a hierarchical set of increasing access authorities.
Access authorities to resources are stored in profiles. Discrete profiles are valid for a single,
named resource and generic profiles are applicable to a group of resources, typically with
similar names. For access permission checks, RACF always chooses the most specific profile
for a resource. Profiles can have an access control list associated with them that contains a
potentially large number of entries for different groups and users, thus allowing the
modeling of complex, fine-grained access controls.
Profiles are assigned to a number of resources within z/OS. This Security Target defines the
resource types analyzed during the evaluation. RACF profiles are also used to manage and
control privileges in z/OS and resources of subsystems that are not part of the evaluated
configuration (e. g. DB2, CICS, JES3).
Access rights for subjects to resources can be set by the profile owner and by the system
administrator.
The TOE allows access decisions by this mechanism for local applications or remote
applications. For local applications the application, or the TOE, uses the RACROUTE
programming interface to perform the access check. Remote applications can perform
similar access checking via LDAP interfaces, if the z/OS ITDS LDAP server is appropriately
configured, by first authenticating (binding) with an ICTX-style identity (DN), and then
providing an extended-operation request indicating that the applications wants do perform
an access check. LDAP will then invoke the ICTX extended operation processing routine
which will check the application’s authority to make such a request, and then will process
the request if authorized. The request specifies the resource to be checked and the RACF
user ID or group name whose access should be checked.
z/OS UNIX DAC mechanism
z/OS implements POSIX-conformant access control for such named objects in the UNIX realm
as UNIX file system objects and UNIX inter-process communication (IPC) objects. Access
types for UNIX file system objects are read, write, and execute/search, and read and write
for UNIX IPC objects. z/OS file system objects provide either access control based on the
permission bits associated with a file, or based on access control lists, which are upward-
compatible with the permission bits algorithm and implement the recommendations from
Portable Operating System Interface for UNIX (POSIX) 1003.1e draft 17.
z/OS LDAP DAC mechanism
The z/OS LDAP server supports several back-end data stores as well as plug-ins. Three of the
data stores (LDBM, CDBM, SDBM) and one plug-in (ICTX) can be used in the evaluated
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configuration. The SDBM back-end allows RACF administration by remote administrators for
systems configured in standard operation mode. The ICTX plug-in allows remote servers to
issue authorization check or auditing requests to RACF in either standard or Labeled Security
Mode. The LDBM back-end allows storage of customer data in either standard or Labeled
Security Mode, and this back-end supports a standard LDAP access control mechanism to
control which authenticated users can access which data. It also supports the possibility of
“public” data, accessed by unauthenticated users, when the administrator has configured
this kind of data and access.
1.4.2.3 Mandatory access control and support for security labels
In addition to DAC, z/OS provides mandatory access control (MAC) functions that are
required for Labeled Security Mode, which impose additional access restrictions on
information flow on security classification. Users and resources can have a security label
specified in their profile. Security labels contain a hierarchical classification (security level),
which specify the sensitivity (for example: public, internal use, or secret), and zero or more
non-hierarchical security categories (for example: PROJECTA or PROJECTB).
The access control enforced by the TOE ensures that users can only read labeled
information if their security labels dominate the information’s label, and that they can only
write to labeled information containers if the container’s label dominates the subject’s, thus
implementing the Bell-LaPadula model of information flow control. The system can also be
configured to allow write-down for certain authorized users.
MAC checks are performed before DAC checks.
Note that security label checking will also occur in standard operation mode, if the
administrator has configured security labels and if resources and users have labels assigned
to them. The exact effects (e.g., whether write-down can occur) depend on several RACF
options, and so the behavior may differ from that imposed by a Labeled Security
configuration, which mandates the setting of certain options.
Users with clearance for multiple security classifications can choose their label at login time
in TSO and for batch jobs submitted to JES, with appropriate defaults assigned if no labels
are chosen. The choice may be restricted by the label assigned to the point of access (the
logical or physical device the user has used to authenticate, e. g. the ID of the terminal, the
IP address, or the ID of the job entry station).
TCP/IP applications that process user login requests must either be restricted to a single
label or must restrict the user label by the label assigned to the point of access.
Specifically for the z/OS LDAP server:
 The LDBM back-end has no mechanisms to perform MAC checking. Instead, each
LDAP server must run with a single security label, matching the classification of the
data in the LDBM database. TCP/IP processing will then ensure that only users
running with that security label will have access to the LDAP data, thus fulfilling the
required MAC checking. As needed, customers may configure multiple z/OS LDAP
servers, each running with a single security label, and users must connect to the
appropriate server that matches their own security label when they want to access
the data.
 The SDBM back-end is prohibited in Labeled Security Mode.
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 The ICTX back-end does not provide any data access functions, and thus technically
does not need to provide MAC checking. However, if the administrator configures
ICTX in Labeled Security Mode then TCP/IP will still control an external server's
connection to LDAP based on the server's security label, and any remote
authorization checking requests will use that security label as part of the decision
making process.
1.4.2.4 Auditing
The TOE provides an auditing capability that allows generating audit records for security-
critical events. RACF provides a number of logging and reporting functions that allow
resource owners and auditors to identify users who attempt to access resources. Audit
records are collected by the System Management Facilities (SMF) into an audit trail, which is
protected from unauthorized modification or deletion by the DAC and (in Labeled Security
Mode) MAC mechanisms. This audit trail can reside directly in MVS data sets, or in an MVS
log stream (which can be automatically off-loaded into MVS data sets), as configured by the
administrator.
The system can be configured to halt on exhaustion of audit trail space to prevent audit data
loss.
Operators are warned when audit trail space consumption reaches a predefined threshold.
RACF always generates audit records for such events as unauthorized attempts to access
the system or changes to the status of the RACF database. The security administrator,
auditors, and other users with appropriate authorization can configure which additional
optional security events are to be logged. In addition to writing records to the audit trail,
messages can be sent to the security console to immediately alert operators of detected
policy violations. RACF provides SMF records for all RACF-protected resources (either
“traditional” or z/OS UNIX-based) as well as for LDAP-based resources.
Remote applications can use an LDAP interface to request that RACF generate an SMF audit
record, if the z/OS ITDS LDAP server is appropriately configured, by first authenticating
(binding) with an ICTX-style identity (DN) and then providing a extended-operation request
indicating that the applications wants do generate an audit record. LDAP will then invoke the
ICTX extended operation processing routine, which will check the application’s authority to
make such a request, and then will process the request if authorized. The request specifies
the information to be audited.
For reporting, auditors can unload all or selected parts of the SMF data for further analysis in
a human-readable formats and can then upload the data to a query or reporting package,
such as DFSORT™ if desired.
1.4.2.5 Object reuse functionality
Reuse of protected objects and of storage is handled by various hardware and software
controls, and by administrative practices.
All memory content of non-shared page frames is cleared before making it accessible to
other address spaces or data spaces. DASD data sets can be purged during deletion with the
RACF ERASE option and tape volumes can be erased on return to the scratch pool. All
resources allocated to UNIX objects are cleared before reuse. Other data pools are under
strict TOE control and cannot be accessed directly by normal users.
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1.4.2.6 Security management
z/OS provides a set of commands and options to adequately manage the TOE’s security
functions. Additionally, the TOE provides the capability of managing users, groups of users,
general resource profiles, and RACF SETROPTS options via the z/OS LDAP server, which can
accept LDAP-format requests from a remote administrator and transform them into RACF
administrative commands via its SDBM backend processing. The TOE also provides a Java
class that allows Java programs to issue commands to manage users and groups. Both the
LDAP SDBM and the Java class ultimately create a RACF command and pass it to RACF using
a programming interface, and then RACF runs the command using the identity associated
with the SDBM session or the Java program. This behaves just the same as when a local
administrator issues the command, including all the same security checking and auditing.
The TOE recognizes several authorities that are able to perform the different management
tasks related to the TOE’s security:
 General security options are managed by security administrators.
 In Labeled Security Mode: management of MAC attributes is performed by security
administrators.
 Management of users and their security attributes is performed by security
administrators. Management of groups (and to some extent users) can be delegated
to group security administrators.
 Users can change their own passwords or password phrases, their default groups,
and their user names (but not their user IDs).
 In Labeled Security Mode: users can choose their security labels at login, for some
login methods. (Note: this also applies in standard operation mode if the
administrator chooses to activate security label processing.)
 Auditors manage the parameters of the audit system (a list of audited events, for
example) and can analyze the audit trail.
 Security administrators can define what audit records are captured by the system.
 Discretionary access rights to protected resources are managed by the owners of the
applicable profiles (or UNIX objects) or by security administrators.
1.4.2.7 Communications Security
z/OS provides means of secure communication between systems sharing the same security
policy. In Labeled Security Mode, communication within TOE parts coupled into a sysplex
can be multilevel, whereas other communication channels are assigned a single security
label. In standard operation mode, labels need not to be assigned and evaluated for any
communication channel.
z/OS TCP/IP provides the means for associating labels with all IP addresses in the network. In
Labeled Security Mode, communication is permitted between any two addresses that have
equivalent labels. In Labeled Security Mode, communication between two multilevel
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addresses requires the explicit labeling of each packet with the sending user's label and is
only permitted over XCF links within the sysplex.
z/OS TCP/IP provides the means to define Virtual IP addresses (VIPAs) with specific labels on
a multilevel system. z/OS TCP/IP considers the user's label when choosing a source address
for communications. z/OS UNIX Systems Services also provides the means to run up to eight
instances of the z/OS TCP/IP stack which can each be restricted to a single label. Either of
these approaches can be used to ensure that most communications between multilevel
systems do not use a multilevel address on both ends and thereby avoid the need for
explicit labeling.
In its evaluated configuration, z/OS supports trusted communication channels for TCP/IP
connections. The confidentiality and integrity of network connections are assured by Secure
Sockets Layer / Transport Layer Security (SSL/TLS) encrypted communication for TCP/IP
connections ([SSLV3], [TLSV1], [TLSV1.1]), which can be used explicitly by applications or
applied transparently to their communications (AT-TLS) without changing the applications
using it (assuming the applications that do not make use of the SSL/TLS capabilities that
allow clients to authenticate to the system using a client-supplied X.509 digital certificate. If
applications accept client certificates then they do need to have specific SSL/TLS-related
processing within the applications.).
In addition to the SSL/TLS connection, z/OS also supports the IP Security (IPSec) protocol
with Internet Key Exchange (IKE) as the key exchange method. This is an additional way to
set up a trusted channel to another trusted IT product for IP-based connections. z/OS also
provides centralized policy management for IPSec policies across multiple z/OS systems in
the network. It also provides centralized management for digital certificates, message
signing, and message verification for IPSec across multiple z/OS systems in the network.
z/OS also supports Kerberos™ version 5 networking protocols, via the Integrated Security
Services Network Authentication Service component, hereafter called z/OS Network
Authentication Service These protocols enable both the client and the server to mutually
authenticate. This authentication mechanism can be utilized with the GSS-API services
provided by the z/OS Network Authentication Service to provide security services to
applications. These services enable encrypted communications channels between clients
and servers that may reside on the same or on different systems.
z/OS also supports, via the optional add-on product IBM Ported Tools for z/OS, the SSH v2
protocol and the ssh-daemon provided services of ssh (secure shell), scp (secure copy), and
sftp (secure ftp) ([SSHV2])
TCP/IP-based communication can be further controlled by the access control function for
TCP/IP connections, which allows controlling of the connection establishment based on
access to the TCP/IP stack in general, individual network address and individual ports on a
per-application or per-user basis.
z/OS provides also a variety of network services, all of which use RACF for identification,
authentication, and access control. In the evaluated configuration, terminal services are
provided by TN3270, telnet, rlogin, rsh, and rexec. File transfer services are provided by the
File Transfer Protocol (FTP), sftp and scp, Web serving functions are provided by the z/OS
HTTP Server.
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1.4.2.8 TSF protection
TSF protection is based on several protection mechanisms that are provided by the
underlying abstract machine:
 Privileged processor instructions are only available to programs running in the
processor’s supervisor state
 Semi-privileged instructions are only available to programs running in an execution
environment that is established and authorized by the TSF
 While in operation, all address spaces, as well as the data and tasks contained
therein, are protected by the memory protection mechanisms of the underlying
abstract machine
The TOE’s address space management ensures that programs running in problem state
cannot access protected memory or resources that belong to other address spaces.
Access to system services – through supervisor call (SVC) or program call (PC) instructions,
for example – is controlled by the system, which requires that subjects who want to perform
security-relevant tasks be authorized appropriately.
The hardware and firmware components that provide the abstract machine for the TOE are
required to be physically protected from unauthorized access. The z/OS Base Control
Program mediates all access to the TOE’s hardware resources themselves, other than
program-visible CPU instruction functions.
Tools are provided in the TOE environment to allow authorized administrators to check the
correct operation of the underlying abstract machine.
In addition to the protection mechanism of the underlying abstract machine, the TOE also
uses software mechanisms like the authorized program facility (APF) or specific privileges for
programs in the UNIX system services environment to protect the TSF.
1.4.3 Configurations
1.4.3.1 Software configuration
The Target of Evaluation, z/OS Version 1 Release 13, consists of:
 z/OS Version 1 Release 13 (V1R13) Common Criteria Evaluated Base Package:
o z/OS Version 1 Release 13 (z/OS V1R13, program number 5694-A01),
o Overlay Generation Language Version 1 (OGL V1R1, program number 5688-
191)
o IBM Print Services Facility™ Version 4 Release 4 for z/OS (PSF V4.4.0, program
number 5655-M32)
 IBM Ported Tools for z/OS V1.2 (FMID HOS1120, program number 5655-M23, optional) along
with the IBM Ported Tools for z/OS: Supplementary Toolkit for z/OS Feature (also optional)
 The following APARs (or their associated PTFs):
APAR PTF
OA35787 UA60116
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APAR PTF
OA36104 UA59869
OA36122 UA59856
OA36127 UA60074
PM36299 UK66798
OA36322 UA61422
OA36879 UA62402
OA36342 UA60574
OA36389 UA60464
OA36063 UA61231
OA37042 UA62306
OA37298 UA62584
OA38075 UA63192
OA36578 UA63322
OA38245 UA63384
OA37035 UA63310
OA38074 UA63381
OA37965 UA63280
OA38022 UA63194
OA38085 UA63353
OA35973 UA62097
OA35974 UA62095
OA35970 UA62047
OA37931 UA63225
Note: References in this document to “HTTP Server” refer to the IBM HTTP Server Base
(FMID HIMW530) and IBM HTTP Server North America Secure (JIMW531) that ship as part of
z/OS, and not to the IBM Ported Tools for z/OS HTTP Server, which must not be used in the
evaluated configuration.
The same software elements are used in the Labeled Security and standard modes of
operation, except as otherwise noted. The mode of operation is defined by the configuration
of the labeling-related options in RACF. Details are described in z/OS Planning for Multilevel
Security and the Common Criteria ([PMLS]).
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The z/OS V1R13 Common Criteria Evaluated Base package, and (if used) IBM Ported Tools
for z/OS must be installed according to the directions delivered with the media and
configured according to the instructions in Chapter 7, “The evaluated configuration for the
Common Criteria” in z/OS Planning for Multilevel Security and the Common Criteria ([PMLS]).
Installations may choose not to use any of the elements delivered within the ServerPac, but
are required to install, configure, and use at least the RACF and ICSF components of the
z/OS Security Server element.
In addition, any software outside the TOE may be added without affecting the security
characteristics of the system, if it cannot run:
 in supervisor state
 as APF-authorized
 with keys 0 through 7
 with UID(0),
 with authority to FACILITY resources BPX.DAEMON, BPX.SERVER, or BPX.SUPERUSER
 with authority to UNIXPRIV resources
This explicitly excludes:
 replacement of any element in the ServerPac providing security functions relevant to
this evaluation by other third-party products;
 installing system exits that run authorized (supervisor state, system key, or APF-
authorized), with the exception of the sample ICHPWX11 and its associated
IRRPHREX routine;
 installing IBM Tivoli Directory Server plug-ins that have not been evaluated;
 using the Authorized Caller Table (ICHAUTAB) in RACF to allow unauthorized
programs to issue RACROUTE REQUEST=VERIFY (RACINIT) or RACROUTE
REQUEST=LIST (RACLIST).
Note: The evaluated software configuration is not invalidated by installing and operating
other appropriately-certified components that possibly run authorized. However the
evaluation of those components must show that the component and the security policies
implemented by the component do not undermine the security policies described in this
document.
The IBM Tivoli Directory Server for z/OS component may be used as the LDAP server, but:
 For client authentication via digital certificates the administrator must configure the
LDAP server to map the certificate to a RACF user ID and to fail the bind if the
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certificate does not map to a RACF user ID. The allowable LDAP configuration
provides three options for forming an LDBM subject:
 LDAP may use the original DN from the certificate; or
 LDAP may replace the original DN with an SDBM-format DN based on the RACF
user ID;
 or LDAP may add the SDBM-format DN to the LDAP subject, giving a subject
with two DNs, either of which will work in LDAP ACLs.
 client authentication using the Kerberos mechanism has not been evaluated for LDAP
and cannot be used in the evaluated configuration.
 authentication via passwords stored in LDAP cannot be used. Authentication must
occur using RACF passwords or password phrases. Note that if an LDBM bind DN is
specified when binding to the server, the password/phrase specified must be for the
RACF user ID associated with that bind DN by the LDAP administrator.;
 only the LDBM and CDBM back-ends and the ICTX plug-in may be used in Labeled
Security Mode. In standard mode the LDBM, CDBM, and SDBM back-ends and the
ICTX plug-in may be used. Other LDAP back-end configurations and plug-ins have not
been evaluated and must not be used.
 (Labeled Security Mode only) Each running instance of the LDAP server must run with
a single, non-SYSMULTI, non-SYSNONE, security label. Multiple server instances may
run at the same time, with the same or different security labels.
Each running instance of the HTTP server must run with a security label that is neither
SYSMULTI nor SYSNONE.
sshd (from IBM Ported Tools for z/OS), may be used, but if used:
 must be configured to use protocol version 2 and either TDES or one of the AES-
based encryption suites,
 must be configured in privilege separation mode, and
 must be configured to allow only password-based (including password phrase)
authentication of users or public-key based authentication of users with the public
keys stored in RACF keyrings. Rhost-based and public-key based user authentication
with the keys stored elsewhere may not be used in the evaluated configuration. In
Labeled Security Mode sshd should be configured with the SYSMULTI security label.
The Network Authentication Service component of the Integrated Security Services
component, if used, and applications exploiting it, must satisfy the following constraints:
 the Network Authentication Service must use the SAF (RACF) registry. The NDBM
registry is not a valid configuration for this evaluation.
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 Cross Realm Trust relationships with foreign Kerberos realms is allowed, but the
foreign KDC must be capable of supporting the same cipher as does the z/OS KDC.
 In order to ensure strong cryptographic protection of Kerberos tickets, Triple DES or
AES should be utilized by the z/OS KDC and any KDC participating in a cross-realm
trust relationship with the z/OS KDC. DES should only be used in network
environments where the threat of cryptographic attacks against the tickets and
Kerberos-protected sessions is deemed low enough to justify the use of these weaker
encryption protocols.
 Applications supporting Kerberos may use a combination of application specific
protocols and the GSS-API functions or the equivalent native platform callable
services (the SAF R_TicketServ and R_GenSec callable services) to authenticate
clients, and in client-server authentication. Only the Kerberos mechanism may be
used by applications that utilize GSS-API or the equivalent native platform functions.
The GSS-API and R_GenSec services also enable the encryption of sensitive
application messages passed via application specific protocols. These services enable
the secure communication between client and server applications. The GSSAPI
services include the message integrity and privacy functions that validate the
authenticity and secure the communications between clients and servers.
The Network File System (NFS) Server may be used, but must be configured with the SAF or
SAFEXP option, to ensure that all file and directory access (except possibly directory
mounting) has appropriate RACF security checks made.
SSL (Secure Sockets Layer) processing, if used, must use SSLv3 protocols. SSL and TLS
(Transport Layer Security), if used, must use use either TDES (168-bit keys) or AES (128- or
256-bit keys) encryption.
IPSec (IP Security) processing, if used, must use either TDES (168-bit keys) or AES (128- or
256-bit keys) encryption.
Any application performing client authentication using client digital certificates over SSL or
TLS must be configured to use RACF profiles in the RACDCERT or DIGTRING classes or
PKCS#11 tokens in ICSF to store the keyrings that contain the application private key and
the allowed Certificate Authority (CA) certificates that may be used to provide the client
certificates that the application will support. The use of gskkyman for this purpose is not part
of the evaluated configuration.
Any client that is delivered with the product that executes with the user's privileges must be
used with care, since the TSF can not protect those clients from potentially hostile programs.
Passwords/phrases a user enters into those client programs that those clients use to pass to
the corresponding server to authenticate the user may potentially be spoofed by hostile
programs running in the user's address space. This includes client programs for telnet,
TN3270, ftp, r-commands, ssh, all LDAP utilities and Kerberos administration utilities that
require the user to enter his password/phrase. When using those client programs the user
should take care that no untrusted potentially hostile program has been called during his
session.
The following elements and element components cannot be used in an evaluated system,
either because they violate the security policies stated in this Security Target or because
they have been removed from the evaluated configuration due to time and resource
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constraints of the evaluation. As they are part of the base system, either they must be not
configured for use or they must be deactivated, as described in Chapter 7, “The evaluated
configuration for the Common Criteria” in
z/OS Planning for Multilevel Security and the Common Criteria:
 All Bulk Data Transfer (BDT) elements: BDT, BDT File-to-File , and BDT Systems
Network Architecture (SNA) NJE
 Connection Manager
 The DFS™ Server Message Block (SMB) (FMID H0H23B0) components of the
Distributed File Service element
 The Enterprise Identity Mapping component of the Integrated Security Services
element
 Infoprint® Server
 JES3
 The Advanced Program-to-Program Communication / Multiple Virtual Storage
(APPC/MVS) component of the BCP
 Process Manager component from the UNIX System Services Element
The use of TCP/IP communication for JES2 NJE has not been part of the evaluation and must
not be used in the evaluated configuration.
The JES2 Execution Batch Monitor (XBM) facility has not been part of the evaluation and
must not be used in the evaluated configuration.
The RACF Remote Sharing Facility has not been part of the evaluation and must not be used
in the evaluated configuration.
The Data Facility Storage Management Subsystem (DFSMS) Object Access Method for
content management type applications must not be used.
The IBM Ported Tools for z/OS HTTP Server V7.0 (FMID HHAP700) must not be used.
For the Communications Server:
 The z/OS FTP server and client, and the z/OS TN3270 server, support both manually-
configured SSL/TLS, or AT-TLS. This evaluation has considered only AT-TLS
configurations, and as a result manual configuration of those components to use SSL
or TLS is not allowed for evaluated configurations.
 The z/OS FTP server and client can support either the protocols from the draft
standard for securing FTP with TLS/SSL, or the protocols from the formal RFC 4217
level of Security FTP with TLS/SSL [RFC4217]. This evaluation has considered only the
formal RFC 4217 level of support, and as a result that option must be used in the
evaluated configuration.
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 The following applications must not be used in Labeled Security configurations, as
noted in the Communications Server IP Configuration Guide: HOMETEST command,
IUCV, LPD, LPQ command, LPR command, LPRM command, LPRSET command,
NCPROUTE, NPF, Portmapper, SMTP, SNMP NetView client, TELNET client command,
TESTSITE command, TNF, VMCF, z/OS UNIX Network SLAPM2 subagent, z/OS UNIX
OMPROUTE SNMP subagent, z/OS UNIX popper, z/OS UNIX RSVP agent, z/OS UNIX
SNMP client command, z/OS UNIX SNMP server and agent, z/OS UNIX Trap Forwarder
Daemon.
1.4.3.2 Hardware configuration
The following assumptions about the technical environment in which the TOE is intended to
be used are made:
The TOE is running within a logical partition provided by a certified version of PR/SM, on the
z/Architecture as implemented by the following hardware platforms:
 IBM System z10 Business Class with CP Assist for Cryptographic Functions (CPACF)
DES/TDES Enablement Feature 3863 active, optionally with CryptoExpress3 card.
 IBM System z10 Enterprise Class with CPACF DES/TDES Enablement Feature 3863
active, optionally with CryptoExpress3 card.
 IBM zEnterprise 114 with CPACF DES/TDES Enablement Feature 3863 active ,
optionally with CryptoExpress3 card, and with or without the zEnterprise BladeCenter
Extension (zBX).
 IBM zEnterprise 196 with CPACF DES/TDES Enablement Feature 3863 active,
optionally with CryptoExpress3 card, and with or without the zEnterprise BladeCenter
Extension (zBX).
In addition, the TOE may run on a virtual machine provided by a certified version of z/VM.
The following peripherals can be used with the TOE, while still preserving the security
functionality:
 All terminals that are supported by the TOE.
 Printers:
o in standard operation mode: any printer that is supported by the TOE.
o in Labeled Security Mode: any printer that is used to print output with
different security labels must support the Guaranteed Print Labeling Function.
Guaranteed print labeling works with a subset of Advanced Function
Presentation™ (AFP™) printers and ensures the integrity of the identification
label by preventing the user from changing the label. Review the printer
hardware documentation or contact the printer vendor to determine if a
printer supports this function.
 All storage devices and backup devices supported by the TOE, such as:
o Direct access storage devices (DASDs), except RVA devices.
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o Tape drives (including encrypting tape drives, though this evaluation has not
specifically examined those cryptographic functions).
 All Ethernet and token-ring network adapters that are supported by the TOE.
Note: The peripherals may be virtualized in the case of the TOE executing within a logical
partition or z/VM. The logical partitioning software and z/VM software is part of the abstract
machine and therefore part of the TOE environment. The logical partitioning software
documentation as well as the z/VM documentation provides the required guidance on how to
set up and configure the logical partitioning software or z/VM and how to define the logical
peripheral devices so the TOE operates securely in the logical partitioning or z/VM
environment.
1.4.4 Structure
The structure of this document is:
 Chapter 1 provides the ST Introduction
 Chapter 2 provides the CC Conformance Claim
 Chapter 3 provides the Security Problem Definition
 Chapter 4 provides the Security Objectives
 Chapter 5 provides the Extended Components Definition
 Chapter 6 provides the Security Requirements for the Operational Environment
 Chapter 7 provides the Security Requirements
 Chapter 8 provides the TOE Summary Specification
 Chapter 9 provides Abbreviations, Terminology and References
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2 CC Conformance Claim
This ST is CC Part 2 extended and CC Part 3 conformant, with a claimed Evaluation
Assurance Level of EAL4, augmented by ALC_FLR.3.
This ST claims conformance to the following Protection Profiles:
 [OSPP] Operating System Protection Profile. Version 2.0 as of 2010-06-01; strict
conformance.
 [OSPP-EIA]: OSPP Extended Package - Extended Identification and Authentication.
Version 2.0 as of 2010-05-28; strict conformance.
 [OSPP-LS]: OSPP Extended Package - Labeled Security. Version 2.0 as of 2010-05-28;
strict conformance.
Common Criteria [CC] version 3.1 revision 3 has been taken as the basis for this
conformance claim.
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3 Security Problem Definition
3.1 Introduction
The statement of the TOE security problem definition describes the security aspects of the
environment in which the TOE is intended to be used and the manner in which it is expected
to be deployed.
To this end, the statement of the TOE security environment identifies the list of assumptions
made on the operational environment (including physical and procedural measures) and the
intended method of use of the product, defines the threats that the product is designed to
counter, and the organizational security policies with which the product is designed to
comply.
3.2 Threat Environment
Threats to be countered by the TOE are characterized by the combination of an asset being
subject to a threat, a threat agent and an adverse action.
3.2.1 Assets
Assets to be protected are:
• Persistent storage objects used to store user data and/or TSF data, where this data
needs to be protected from any of the following operations:
• Unauthorized read access
• Unauthorized modification
• Unauthorized deletion of the object
• Unauthorized creation of new objects
• Unauthorized management of object attributes
• Transient storage objects, including network data
• TSF functions and associated TSF data
• The resources managed by the TSF that are used to store the above-mentioned
objects, including the metadata needed to manage these objects
3.2.2 Threat agents
Threat agents are external entities that potentially may attack the TOE. They satisfy one or
more of the following criteria:
• External entities not authorized to access assets may attempt to access them either
by masquerading as an authorized entity or by attempting to use TSF services
without proper authorization.
• External entities authorized to access certain assets may attempt to access other
assets they are not authorized to either by misusing services they are allowed to use
or by masquerading as a different external entity.
• Untrusted subjects may attempt to access assets they are not authorized to either by
misusing services they are allowed to use or by masquerading as a different subject.
Threat agents are typically characterized by a number of factors, such as expertise,
available resources, and motivation, with motivation being linked directly to the value of the
assets at stake. The TOE protects against intentional and unintentional breach of TOE
security by attackers possessing an enhanced-basic attack potential.
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The following threats are addressed by the TOE. All threats have been copied from the OSPP.
As in the OSPP, there are no threats and policies to justify the assurance level.
3.2.3 Threats countered by the TOE
T.ACCESS.TSFDATA
A threat agent might read or modify TSF data without the necessary authorization
when the data is stored or transmitted.
T.ACCESS.USERDATA
A threat agent might gain access to user data stored, processed or transmitted by the
TOE without being appropriately authorized according to the TOE security policy.
T.ACCESS.TSFFUNC
A threat agent might use or modify functionality of the TSF without the necessary
privilege to grant itself or others unauthorized access to TSF data or user data.
T.ACCESS.COMM
A threat agent might access a communication channel that establishes a trust
relationship between the TOE and another remote trusted IT system or masquerade as
another remote trusted IT system.
T.RESTRICT.NETTRAFFIC
A threat agent might get access to information or transmit information to other
recipients via network communication channels without authorization for this
communication attempt by the information flow control policy.
T.IA.MASQUERADE
A threat agent might masquerade as an authorized entity including the TOE itself or a
part of the TOE in order to gain unauthorized access to user data, TSF data, or TOE
resources.
T.IA.USER
A threat agent might gain access to user data, TSF data or TOE resources with the
exception of public objects without being identified and authenticated.
T.DATA_NOT_SEPARATED
The TOE may not adequately separate data on the basis of its sensitivity label, thereby
allowing information to flow illicitly from or to users.
3.3 Assumptions
This section describes the security aspects of the environment in which the TOE is intended
to be used. It includes information about the physical, personnel, procedural, and
connectivity aspects of the environment.
The TOE is assured to provide effective security measures in a cooperative non-hostile
environment only if it is installed, managed, and used correctly. The operational
environment must be managed in accordance with user/administrator guidance
documentation. The following specific conditions are assumed to exist in an environment
where the TOE is employed.
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3.3.1 Environment of use of the TOE
3.3.1.1 Physical
The TOE is intended for application in user areas that have physical control and monitoring.
It is assumed that the following physical conditions will exist:
A.PHYSICAL
It is assumed that the IT environment provides the TOE with appropriate physical
security, commensurate with the value of the IT assets protected by the TOE.
3.3.1.2 Personnel
A.MANAGE
The TOE security functionality is managed by one or more competent individuals. The
system administrative personnel are not careless, willfully negligent, or hostile, and will
follow and abide by the instructions provided by the guidance documentation.
A.AUTHUSER
Authorized users possess the necessary authorization to access at least some of the
information managed by the TOE and are expected to act in a cooperating manner in a
benign environment.
A.TRAINEDUSER
Users are sufficiently trained and trusted to accomplish some task or group of tasks
within a secure IT environment by exercising complete control over their user data.
3.3.1.3 Procedural
A.DETECT
Any modification or corruption of security-enforcing or security-relevant files of the
TOE, user or the underlying platform caused either intentionally or accidentally will be
detected by an administrative user.
A.PEER.MGT
All remote trusted IT systems trusted by the TSF to provide TSF data or services to the
TOE, or to support the TSF in the enforcement of security policy decisions are assumed
to be under the same management control and operate under security policy
constraints compatible with those of the TOE.
A.PEER.FUNC
All remote trusted IT systems trusted by the TSF to provide TSF data or services to the
TOE, or to support the TSF in the enforcement of security policy decisions are assumed
to correctly implement the functionality used by the TSF consistent with the
assumptions defined for this functionality.
3.3.1.4 Connectivity
A.CONNECT
All connections to and from remote trusted IT systems and between physically-
separate parts of the TSF not protected by the TSF itself are physically or logically
protected within the TOE environment to ensure the integrity and confidentiality of the
data transmitted and to ensure the authenticity of the communication end points.
3.4 Organizational Security Policies
P.ACCOUNTABILITY
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The users of the TOE shall be held accountable for their security-relevant actions within
the TOE.
P.USER
Authority shall only be given to users who are trusted to perform the actions correctly.
P.I&A.REMOTE
Remote trusted IT systems shall be able to obtain identification and authentication
decisions from the TOE based on credentials transmitted by a remote trusted IT system
to the TOE.
P.CLEARANCE
The system must limit the information flow between protected resources and
authorized users based on whether the user's sensitivity label is appropriate for the
labeled information.
P.LABELED_OUTPUT
The beginning and end of all paged, hardcopy output must be marked with sensitivity
labels that properly represent the sensitivity label of the output.
P.RESOURCE_LABELS
All resources accessible by subjects and all subjects must have associated labels
identifying the sensitivity levels of data contained therein.
P.USER_CLEARANCE
All users must have a clearance level identifying the maximum sensitivity levels of
data they may access.
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4 Security Objectives
This section defines the security objectives of the TSF and its supporting environment.
Security objectives, categorized as either IT security objectives or non-IT security objectives,
reflect the stated intent to counter identified threats, comply with any organizational
security policies identified, or both. All of the identified threats and organizational policies
are addressed under one of the following categories.
4.1 Objectives for the TOE
O.AUDITING
The TSF must be able to record defined security-relevant events (which usually include
security-critical actions of users of the TOE). The TSF must protect this information and
present it to authorized users if the audit trail is stored on the local system. The
information recorded for security-relevant events must contain the time and date the
event happened and, if possible, the identification of the user that caused the event,
and must be in sufficient detail to help the authorized user detect attempted security
violations or potential misconfiguration of the TOE security features that would leave
the IT assets open to compromise.
O.CRYPTO.NET
The TSF must allow authorized users to remotely access the TOE using a
cryptographically-protected network protocol that ensures integrity and confidentiality
of the transported data and is able to authenticate the end points of the
communication. Note that the same protocols may also be used in the case where the
TSF is physically separated into multiple parts that must communicate securely with
each other over untrusted network connections.
O.DISCRETIONARY.ACCESS
The TSF must control access of subjects and/or users to named resources based on
identity of the object. The TSF must allow authorized users to specify for each access
mode which users/subjects are allowed to access a specific named object in that
access mode.
O.NETWORK.FLOW
The TOE shall mediate communication between sets of TOE network interfaces,
between a network interface and the TOE itself, and between subjects in the TOE and
the TOE itself in accordance with its security policy.
O.SUBJECT.COM
The TOE shall mediate communication between subjects acting with different subject
security attributes in accordance with its security policy.
O.I&A
The TOE must ensure that users have been successfully authenticated before allowing
any action the TOE has defined to provide to authenticated users only.
O.MANAGE
The TSF must provide all the functions and facilities necessary to support the
authorized users that are responsible for the management of TOE security mechanisms
and must ensure that only authorized users are able to access such functionality.
O.TRUSTED_CHANNEL
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The TSF must be designed and implemented in a manner that allows for establishing a
trusted channel between the TOE and a remote trusted IT system that protects the
user data and TSF data transferred over this channel from disclosure and undetected
modification and prevents masquerading of the remote trusted IT system.
O.I&A.REMOTE
The TOE shall allow remote trusted IT systems to transmit user credentials to the TOE
which are used to perform a local identification and authentication policy decision. This
decision is communicated back to one or more remote trusted IT systems based on the
identification and authentication policy.
O.I&A.MULTIPLE
The TOE shall allow the concurrent use of multiple identification and authentication
mechanisms implementing the identification and authentication policy.
O.LS.CONFIDENTIALITY
The TOE will control information flow between entities and resources based upon the
sensitivity labels of users and resources.
O.LS.PRINT
The TOE will provide the capability to mark printed output with accurate labels based
on the sensitivity label of the user causing the output.
O.LS.LABEL
The TOE will provide the capability to label all subjects, and all objects accessible by
subjects, to restrict information flow based on the sensitivity labels.
O.CRYPTO.BASIC
The TSF will provide the following cryptographic services for general use by authorized
entities, using support from the underlying platform:
 symmetric and asymmetric ciphers
 message digest generation
 symmetric and asymmetric key generation
4.2 Objectives for the Operational Environment
OE.ADMIN
Those responsible for the TOE are competent and trustworthy individuals, capable of
managing the TOE and the security of the information it contains.
OE.REMOTE
If the TOE relies on remote trusted IT systems to support the enforcement of its policy,
those systems provide the functions required by the TOE and are sufficiently protected
from any attack that may cause those functions to provide false results.
OE.INFO_PROTECT
Those responsible for the TOE must establish and implement procedures to ensure that
information is protected in an appropriate manner. In particular:
• All network and peripheral cabling must be approved for the transmittal of the
most sensitive data held by the system. Such physical links are assumed to be
adequately protected against threats to the confidentiality and integrity of the
data transmitted.
• DAC protections on security-relevant files (such as audit trails and
authentication databases) shall always be set up correctly.
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• Users are authorized to access parts of the data managed by the TOE and are
trained to exercise control over their own data.
OE.INSTALL
Those responsible for the TOE must establish and implement procedures to ensure that
the hardware, software and firmware components that comprise the system are
distributed, installed and configured in a secure manner supporting the security
mechanisms provided by the TOE.
OE.MAINTENANCE
Authorized users of the TOE must ensure that the comprehensive diagnostics facilities
provided by the product are invoked at every scheduled preventative maintenance
period.
OE.PHYSICAL
Those responsible for the TOE must ensure that those parts of the TOE critical to
enforcement of the security policy are protected from physical attack that might
compromise IT security objectives. The protection must be commensurate with the
value of the IT assets protected by the TOE.
OE.RECOVER
Those responsible for the TOE must ensure that procedures and/or mechanisms are
provided to assure that after system failure or other discontinuity, recovery without a
protection (security) compromise is achieved.
OE.TRUSTED.IT.SYSTEM
The remote trusted IT systems implement the protocols and mechanisms required by
the TSF to support the enforcement of the security policy.
These remote trusted IT systems are under the same management domain as the TOE, are
managed based on the same rules and policies applicable to the TOE, and are physically and
logically protected equivalent to the TOE.
4.3 Security Objectives Rationale
4.3.1 Security Objectives Coverage
The following table provides a mapping of TOE objectives to threats and policies, showing
that each objective counters or enforces at least one threat or policy, respectively.
Objective Threats / OSPs
O.AUDITING P.ACCOUNTABILITY
O.CRYPTO.NET T.ACCESS.TSFDATA
T.ACCESS.USERDATA
T.ACCESS.TSFFUNC
O.DISCRETIONARY.ACCESS T.ACCESS.TSFDATA
T.ACCESS.USERDATA
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Objective Threats / OSPs
O.NETWORK.FLOW T.RESTRICT.NETTRAFFIC
O.SUBJECT.COM T.ACCESS.TSFDATA
T.ACCESS.USERDATA
O.I&A T.IA.MASQUERADE
T.IA.USER
O.MANAGE T.ACCESS.TSFFUNC
P.ACCOUNTABILITY
P.USER
O.TRUSTED_CHANNEL T.ACCESS.COMM
O.I&A.REMOTE P.I&A.REMOTE
O.I&A.MULTIPLE P.I&A.REMOTE
O.LS.CONFIDENTIALITY T.DATA_NOT_SEPARATED
P.CLEARANCE
P.USER_CLEARANCE
O.LS.PRINT P.LABELED_OUTPUT
O.LS.LABEL P.RESOURCE_LABELS
P.USER_CLEARANCE
O.CRYPTO.BASIC T.ACCESS.USERDATA
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Table 1: Mapping of security objectives to threats and policies
The following table provides a mapping of the objectives for the Operational Environment to
assumptions, threats and policies, showing that each objective holds, counters or enforces
at least one assumption, threat or policy, respectively.
Objective Assumptions / Threats / OSPs
OE.ADMIN A.MANAGE
A.AUTHUSER
A.TRAINEDUSER
OE.REMOTE A.CONNECT
T.ACCESS.COMM
OE.INFO_PROTECT A.PHYSICAL
A.MANAGE
A.AUTHUSER
A.TRAINEDUSER
P.USER
OE.INSTALL A.MANAGE
A.DETECT
OE.MAINTENANCE A.DETECT
OE.PHYSICAL A.PHYSICAL
OE.RECOVER A.MANAGE
A.DETECT
OE.TRUSTED.IT.SYSTEM A.PEER.MGT
A.PEER.FUNC
A.CONNECT
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Table 2: Mapping of security objectives for the Operational Environment to
assumptions, threats and policies
4.3.2 Security Objectives Sufficiency
The following rationale provides justification that the security objectives are suitable to
counter each individual threat and that each security objective tracing back to a threat,
when achieved, actually contributes to the removal, diminishing or mitigation of that threat:
Threat Rationale for security objectives
T.ACCESS.TSFDATA The threat of accessing TSF data without proper
authorization is removed by:
• O.CRYPTO.NET requiring cryptographically-
protected communication channels for data
including TSF data controlled by the TOE in transit
between trusted IT systems,
• O.DISCRETIONARY.ACCESS requiring that data,
including TSF data stored with the TOE, have
discretionary access control protection,
• O.SUBJECT.COM requiring the TSF to mediate
communication between subjects.
T.ACCESS.USERDATA The threat of accessing user data without proper
authorization is removed by:
• O.CRYPTO.NET requiring cryptographically-
protected communication channels for data
including user data controlled by the TOE in transit
between trusted IT systems,
• O.DISCRETIONARY.ACCESS requiring that data
including user data stored with the TOE, have
discretionary access control protection,
• O.SUBJECT.COM requiring the TSF to mediate
communication between subjects.
• O.CRYPTO.BASIC requiring the TSF to provide
cryptographic services for general use by
authorized entities, including encryption,
decryption, and message digest generation
services.
T.ACCESS.TSFFUNC The threat of accessing TSF functions without proper
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Threat Rationale for security objectives
authorization is removed by:
• O.CRYPTO.NET requiring cryptographically-
protected communication channels to limit which
TSF functions are accessible to external entities,
• O.MANAGE requiring that only authorized users
utilize management TSF functions.
T.ACCESS.COMM The threat of accessing a communication channel that
establishes a trust relationship between the TOE and
another remote trusted IT system is removed by:
• O.TRUSTED_CHANNEL requiring that the TOE
implements a trusted channel between itself and a
remote trusted IT system protecting the user data
and TSF data transferred over this channel from
disclosure and undetected modification,
• OE.REMOTE requiring that those systems providing
the functions required by the TOE are sufficiently
protected from any attack that may cause those
functions to provide false results.
T.RESTRICT.NETTRAFFIC The threat of accessing information or transmitting
information to other recipients via network communication
channels without authorization for this communication
attempt is removed by:
• O.NETWORK.FLOW requiring the TOE to mediate the
communication between itself and remote entities
in accordance with its security policy.
T.IA.MASQUERADE The threat of masquerading as an authorized entity in
order to gain unauthorized access to user data, TSF data or
TOE resources is removed by:
• O.I_A requiring that each entity interacting with the
TOE is properly identified and authenticated before
allowing any action the TOE is defined to provide to
authenticated users only.
T.IA.USER The threat of accessing user data, TSF data or TOE
resources without being identified and authenticated is
removed by:
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Threat Rationale for security objectives
• O.I_A requiring that each entity interacting with the
TOE is properly identified and authenticated before
allowing any action the TOE has defined to provide
to authenticated users only.
T.DATA_NOT_SEPARATED The threat of not adequately separating data on the basis
of its sensitivity label, thereby allowing information to flow
illicitly from or to users is removed by:
• O.LS.CONFIDENTIALITY requiring the TOE to control
information flow between entities and resources
based upon the sensitivity labels of users and
resources.
Table 3: Sufficiency of objectives countering threats
The following rationale provides justification that the security objectives for the environment
are suitable to cover each individual assumption, that each security objective for the
environment that traces back to an assumption about the environment of use of the TOE,
when achieved, actually contributes to the environment achieving consistency with the
assumption, and that if all security objectives for the environment that trace back to an
assumption are achieved, the intended usage is supported:
Assumption Rationale for security objectives
A.PHYSICAL The assumption on the IT environment to provide the TOE with
appropriate physical security, commensurate with the value of the
IT assets protected by the TOE is covered by:
• OE.INFO_PROTECT requiring the approval of network and
peripheral cabling,
• OE.PHYSICAL requiring physical protection.
A.MANAGE The assumptions on the TOE security functionality being managed
by one or more competent trustworthy individuals is covered by:
• OE.ADMIN requiring trustworthy personnel managing the
TOE,
• OE.INFO_PROTECT requiring personnel to ensure that
information is protected in an appropriate manner,
• OE.INSTALL requiring personnel to ensure that components
that comprise the system are distributed, installed and
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Assumption Rationale for security objectives
configured in a secure manner supporting the security
mechanisms provided by the TOE,
• OE.RECOVER requiring personnel to assure that after
system failure or other discontinuity, recovery without a
protection (security) compromise is achieved.
A.AUTHUSER The assumption on authorized users to possess the necessary
authorization to access at least some of the information managed
by the TOE and to act in a cooperating manner in a benign
environment is covered by:
• O.I_A ensuring that users have been successfully
authenticated before allowing any action the TOE has
defined to provide to authenticated users only,
• OE.ADMIN ensuring that those responsible for the TOE are
competent and trustworthy individuals, capable of
managing the TOE and the security of the information it
contains,
• OE.INFO_PROTECT requiring that DAC protections on
security-relevant files (such as audit trails and
authentication databases) shall always be set up correctly
and that users are authorized to access parts of the data
maintained by the TOE.
A.TRAINEDUSER The assumptions on users to be sufficiently trained and trusted to
accomplish some task or group of tasks within a secure IT
environment by exercising complete control over their user data is
covered by:
• OE.ADMIN requiring competent personnel managing the
TOE,
• O.MANAGE requiring the TSF to ensure that only authorized
users are able to access such functionality,
• OE.INFO_PROTECT requiring that those responsible for the
TOE must establish and implement procedures to ensure
that information is protected in an appropriate manner and
that users are trained to exercise control over their own
data.
A.DETECT The assumption that modification or corruption of security-
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Assumption Rationale for security objectives
enforcing or security-relevant files will be detected by an
administrative user is covered by:
• OE.INSTALL requiring an administrative user to ensure that
the TOE is distributed, installed and configured in a secure
manner supporting the security mechanisms provided by
the TOE,
• OE.MAINTENANCE requiring an administrative user to
ensure that the diagnostics facilities are invoked at every
scheduled preventative maintenance period, verifying the
correct operation of the TOE,
• OE.RECOVER requiring an administrative user to ensure that
procedures and/or mechanisms are provided to assure that
after system failure or other discontinuity, recovery without
a protection (security) compromise is achieved.
A.PEER.MGT The assumption on all remote trusted IT systems to be under the
same management control and operate under security policy
constraints compatible with those of the TOE is covered by:
• OE.TRUSTED.IT.SYSTEM requiring that these remote trusted
IT systems are under the same management domain as the
TOE, and are managed based on the same rules and policies
applicable to the TOE.
A.PEER.FUNC The assumption on all remote trusted IT systems to correctly
implement the functionality used by the TSF consistent with the
assumptions defined for this functionality is covered by:
• OE.TRUSTED.IT.SYSTEM requiring that the remote trusted IT
systems implement the protocols and mechanisms required
by the TSF to support the enforcement of the security
policy.
A.CONNECT The assumption on all connections to and from remote trusted IT
systems and between physically separate parts of the TSF not
protected by the TSF itself are physically or logically protected is
covered by:
• OE.REMOTE requiring that remote trusted IT systems
provide the functions required by the TOE and are
sufficiently protected from any attack that may cause those
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Assumption Rationale for security objectives
functions to provide false results,
• OE.TRUSTED.IT.SYSTEM demanding the physical and logical
protection equivalent to the TOE.
Table 4: Sufficiency of objectives holding assumptions
The following rationale provides justification that the security objectives are suitable to
cover each individual organizational security policy, that each security objective that traces
back to an OSP, when achieved, actually contributes to the implementation of the OSP, and
that if all security objectives that trace back to an OSP are achieved, the OSP is
implemented:
OSP Rationale for security objectives
P.ACCOUNTABILITY The policy to hold users accountable for their security-
relevant actions within the TOE is implemented by:
• O.AUDITING providing the TOE with audit functionality,
• O.MANAGE allowing the management of this function.
P.USER The policy to match the trust given to a user and the actions
the user is given authority to perform is implemented by:
• O.MANAGE allowing appropriately-authorized users to
manage the TSF,
• OE.INFO_PROTECT, which requires that users are
trusted to use the protection mechanisms of the TOE
to protect their data.
P.I&A.REMOTE The policy to obtain identification and authentication
decisions from the TOE based on credentials transmitted by a
remote trusted IT system to the TOE is implemented by:
• O.I&A.REMOTE allowing remote trusted IT systems to
transmit user credentials to the TOE which are used to
perform a local identification and authentication policy
decision. This decision is communicated back to one or
more remote trusted IT systems based on the
identification and authentication policy.
• O.I&A.MULTIPLE allowing the concurrent use of
multiple identification and authentication mechanisms
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OSP Rationale for security objectives
implementing the identification and authentication
policy.
P.CLEARANCE The policy to limit the information flow between protected
resources and authorized users based on the user's sensitivity
label being appropriate for the labeled information is
implemented by:
• O.LS.CONFIDENTIALITY requiring the TOE to control
information flow between entities and resources based
upon the sensitivity labels of users and resources.
P.LABELED_OUTPUT The policy to provide the capability to mark printed output
with accurate labels based on the sensitivity label of the user
causing the output is implemented by:
• O.LS.PRINT providing the capability to mark printed
output with accurate labels based on the sensitivity
label of the user causing the output.
P.RESOURCE_LABELS The policy that resources accessible by subjects and all
subjects must have associated labels identifying the
sensitivity levels of data contained therein is implemented by:
• O.LS.LABEL providing the capability to label all
subjects and all objects accessible by subjects to
restrict the information flow based on the sensitivity
labels.
P.USER_CLEARANCE The policy that all users must have a clearance level
identifying the maximum sensitivity levels of data they may
access is implemented by:
• O.LS.CONFIDENTIALITY requiring the TOE to control
information flow between entities and resources based
upon the sensitivity labels of users and resources.
• O.LS.LABEL ensures that object and subject are
accurately labeled for the TOE to enforce the label
policy.
Table 5: Sufficiency of objectives enforcing Organizational Security Policies
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5 Extended Components Definition
[OSPP] defines three extended components:
• FCS_RNG.1: Random number generation
 FDP_RIP.3: Full residual information protection of subjects , and
 FIA_USB.2: Enhanced user-subject binding.
[OSPP-EIA] defines two extended components:
 FIA_UAU.8: Authentication policy decisions, and
 FIA_UID.3: Identification policy decisions.
This Security Target defines the following additional extended components:
 FCS_COP_EXT.1: Cryptographic operation with platform support
 FCS_CKM_EXT.1: Cryptographic key generation with platform support
5.1 FCS_CKM_EXT.1 Cryptographic key generation with
platform support
FCS_CKM_EXT.1 requires the TOE to provide functions for the generation of cryptographic
keys where the TOE uses the support of the underlying platform for this functionality.
FCS_CKM_EXT.1 is modeled after the component FCS_CKM.1 defined in part 2 of the CC with
possibility to define the support used from the underlying platform.
Hierarchical to: No other components.
Dependencies: [FCS_CKM.2 Cryptographic key distribution, or
FCS_COP.1 Cryptographic operation]
FCS_CKM.4 Cryptographic key destruction
FCS_CKM_EXT.1.1 The TSF shall generate cryptographic keys in accordance with a
specified cryptographic key generation algorithm [assignment:
cryptographic key generation algorithm] and specified cryptographic
key sizes [assignment: cryptographic key sizes] that meet the
following: [assignment: list of standards] using the following support
from the underlying platform [assignment: function(s) used from the
underlying platform to support the SFR].
5.2 FCS_COP_EXT.1 Cryptographic operation with platform
support
FCS_COP_EXT.1 requires the TOE to provide functions for cryptographic operations where
the TOE uses the support of the underlying platform for this functionality. FCS_COP_EXT.1 is
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modeled after the component FCS_COP.1 defined in part 2 of the CC with possibility to
define the support used from the underlying platform.
Hierarchical to: No other components.
Dependencies: [FDP_ITC.1 Import of user data without security attributes, or
FDP_ITC.2 Import of user data with security attributes, or
FCS_CKM.1 Cryptographic key generation]
FCS_CKM.4 Cryptographic key destruction
FCS_COP_EXT.1.1 The TSF shall perform [assignment: list of cryptographic operations]
in accordance with a specified cryptographic algorithm [assignment:
cryptographic algorithm] and cryptographic key sizes [assignment:
cryptographic key sizes] that meet the following: [assignment: list of
standards] using the following support functionality provided by the
underlying platform [assignment: function(s) used from the
underlying platform to support the SFR].
Rationale:
A TOE may provide functionality for key generation to an application where the
implementation of this functionality uses functions provided by the underlying platform.
z/OS is just one example. Such functionality provided by the platform may just be a physical
noise source used for seeding the random number generator used in the key generation
process or may be up to the generation of key material, which the TSF then protect and
manage. For example a TOE may include a cryptographic coprocessor capable of securely
generating cryptographic key material. Such a coprocessor may have been subject to a
different analysis for the correctness and efficiency of the operation it provides ans in
addition may even offer a higher level of physical protection than the TOE itself. Optionally
such coprocessors may even generate key material that does not leave the coprocessor
unencrypted, e. g. in the case of a coprocessor used for a system implementing a
Certification Authority. In such a case the TSF of the TOE itself may not be involved in the
key generation process other than controlling the conditions that need to be satisfied to
initiate the key generation process on the coprocessor and later controlling the conditions
that need to be satisfied in order to invoke a function on the coprocessor that uses the key
material securely stored in the coprocessor. Another example is where the TSF of the TOE
invoke the coprocessor for the generation of cryptographic key material, but then keep this
key material under its own control protected from direct access by entities outside of the
TSF. In such cases the TSF may control the use of the key material by applications which just
request the use of this key material through a key handle where the TSF control if the caller
of the service is allowed to use the key associated with the key handle. In all those cases the
TSF offer functionality for the generation of cryptographic keys to its users, although the TSF
does not implement all aspects of this function itself. Still such functionality is an important
security functionality and it is important to validate that the part of the functionality
provided by the TSF is done correctly, can not be bypassed and does not exhibit flaws that
can be used to obtain information about the key material other than the ones the user is
authorized to.
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The use of cryptographic functions provided by the underlying platform in order to
implement cryptographic services an operating system uses and provides to subjects gets
more and more common, especially since the platform may provide better physical
protection of critical security parameter and may also provide significantly better
performance.
The extended SFRs defined above allow the specification of cryptographic functions
provided by z/OS and widely used by applications via the ICSF interfaces.
Since cryptographic functions may have specific vulnerabilities that can only be analyzed
with sufficient information about the specifics of the implementation of the function, it is
important to describe the support provided by the underlying platform in order to
demonstrate the limits of the evaluation of the TOE In the case of z/OS, this Security Target
describes the cryptographic functionality provided by the underlying platform as Security
Functional Requirements for the IT environment, which shows to the reader the functionality
implemented by the platform as part of the IT environment. A user of z/OS may then ask for
separate validations of those functions as required for his operational environment.
6 Security Requirements for the Operational
Environment
Although CC Version 3.1 does not mandate the use of security requirements for the IT
environment, it allows to define the security objectives for the IT environment to the level of
detail useful for the understanding and evaluation of a TOE. In the case of z/OS the security
functionality defined in chapter 7 of this Security Target depends on the supporting
functionality defined in this section. The authors of this Security Target decided (also for
compatibility with Security Targets used for previous versions of the TOE) to define this
functionality using the structure of Security Functional Requirements.
There are several components in the IT environment that are used by the TOE to implement
the security functional requirements. Those are:
 The instructions provided by the underlying processor (named z/Architecture)
 The “CP Assist for Cryptographic Functions” (CPACF). Although this feature is
implemented as instructions of the processor and therefore is part of the
z/Architecture, it has been decided by the authors of this Security Target to treat
them separate from the other instructions. One reason is that some features of
CPACF are available on selected processor types only. This is expressed in the SFRs
related to CPACF.
 The “CryptoExpress 3” (CEX3) coprocessor board. This board can be operated in two
modes, coprocessor mode (CEX3C) and an accelerator mode (CEX3A). The CEX3 is a
PCI board with its own processor and cryptographic coprocessors. This board provides
a set of cryptographic functions broader than the CPACF.
In CEX3C mode the coprocessor provides a separate, physically protected
environment to store cryptographic keys and perform cryptographic operations.
In CEX3A mode the board provides functions for fast long integer arithmetic that can
be used for fast implementation of asymmetric cryptographic algorithms like RSA.
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This coprocessor is optional. The ICSF component of the TOE checks for the
availability of one or more of those boards.
On the z114 and z196 processors CEX3C offers ECC (elliptic curve cryptographic)
functions not available on the z10.
The CEX3 coprocessors is used in a way transparent to the user when he uses the ICSF
component of the TOE. ICSF scans for the available cryptographic coprocessors and uses
them accordingly. The security functional requirements listed here are related to the use of
those coprocessors by the functions claimed in this Security Target that rely on
cryptographic operations. While the coprocessors may implement more cryptographic
functions than those claimed here, those are not used to support any of the claims made in
chapter 7.1 of this Security Target.
When using the PKCS#11 functions of ICSF for RSA or Elliptic Curve cryptographic functions,
ICSF checks for the availability of a CryptoExpress3 coprocessor in coprocessor mode and
will use the coprocessor when available and when it implements the basic cryptographic
algorithm. If no coprocessor is available or if the cryptographic algorithm is not implemented
by the coprocessor, ICSF uses s software implementation of those algorithms. When using
the CCA functions, ICSF will always attempt to use a CryptoExpress3 coprocessor and will fail
the call if no CryptoExpress3 coprocessor is available or if the required support for the
function is not provided by the CryptoExpress3 coprocessor. The SFRs for cryptographic
operations have been refined with specification that allows the reader to determine when
support for cryptographic algorithms is provided by CPACF or a CryptoExpress3 coprocessor.
While the functions of the coprocessors can only be called using ICSF, the processor
instructions implemented by the CPACF are available for all programs. The claims made in
this section are only for the use of those functions by the TSF. While this checks for the
correct implementation of the basic cryptographic algorithms for those instructions, no claim
can be made here for applications not part of the TSF that use those instructions. They may
still use those instructions incorrectly or fail to protect cryptographic keys appropriately.
The other part of the IT environment where requirements are stated is the underlying
abstract machine as implemented by the z/Architecture that has to provide the mechanism
to protect the TSF and TSF data from unauthorized access and tampering. This is expressed
with the following security functional requirement for the processor used to execute TOE
software:
6.1 General security requirements for the abstract
machine
6.1.1 Subset access control (FDP_ACC.1(E))
FDP_ACC.1.1 The abstract machine shall enforce the memory access control policy on
instructions as subjects and memory locations and processor registers as
objects.
6.1.2 Security-attribute-based access control (FDP_ACF.1(E))
FDP_ACF.1.1 The abstract machine shall enforce the memory access control policy to
objects based on the processor state (problem or supervisor).
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FDP_ACF.1.2 The abstract machine shall enforce the following rules to determine if an
operation among controlled subjects and controlled objects is allowed:
access to memory locations and special registers is based on the
processor state and the state of the memory management unit. Access to
dedicated processor registers is allowed only if the processor is in
supervisor state when the instruction accessing the register is executed.
FDP_ACF.1.3 The abstract machine shall explicitly authorize access of subjects to
objects based on the following additional rules: some dedicated processor
registers may be read but not modified when the instruction accessing the
register is in problem mode.
FDP_ACF.1.4 The abstract machine shall explicitly deny access of subjects to objects
based on the following rule: none.
Application note: The precise definition of the objects and the rules for the access
control policy differ slightly depending on the processor type. Although the underlying
hardware / firmware that enforces this policy is part of the IT environment, it is analyzed
and tested to provide the support required for the enforcement of the TOE's self-
protection. The criteria for the analysis of the high-level design require the analysis of the
underlying hardware and firmware and the security functional requirements stated here
are taken as the basis for this analysis.
6.1.3 Static attribute initialization (FMT_MSA.3(E))
FMT_MSA.3.1 The abstract machine shall enforce the memory access control policy to
provide permissive default values for security attributes that are used to
enforce the SFP.
FMT_MSA.3.2 The abstract machine shall allow the no role to specify alternative initial
values to override the default values when an object or information is
created.
Application note: The “default” values in this case are seen as the values the processor
has after startup. They have to be “permissive”, because the initialization routine needs
to set up the memory management unit and the device register. With respect to the
hardware, there is no “role” model implemented, but the access control policy is purely
based on a single attribute (“user” or “supervisor” state) that can not be managed or
assigned to a “user”. The attribute changes under well-defined conditions (when the
processor encounters an exception an interrupt, or when a call gate for a higher ring of
privilege is called). The security requirement FMT_MSA.1 was therefore not applicable
because the security attribute cannot be “managed”. For this reason, there is also no
security requirement FMT_SMR.1 included, because there are no ”roles” that need to be
managed or assigned to “users”. The dependency of FMT_MSA.3 to FMT_MSA.1 and
FMT_SMR.1 is therefore unresolved.
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6.2 Security requirements for CPACF
The CP assist for cryptographic functions (CPACF) is a feature of the z/Architecture that
provides instructions to perform cryptographic operations. Those instructions are part of the
general instruction set of the processor and available to programs executing in any mode
and with any PSW key. The instructions provide support for the basic cryptographic
operations only. No support for key management, key protection or key generation is
provided. This has to be performed by the software using the instructions. The instructions
are specified in [ZARCH].
6.2.1 Cryptographic operation (DES) (FCS_COP.1(1E))
FCS_COP.1.1 The CPACF shall perform encryption and decryption in accordance with a
specified cryptographic algorithm TDES and cryptographic key sizes 112
and 168 bit that meet the following: NIST Special Publication 800-67.
Application note: This function is provided by the “Cipher Message” and “Cipher
Message with Chaining” instructions. Function Code 1 specifies DES, function code 2
specifies two key TDES and function code 3 specifies 3 key TDES.
6.2.2 Cryptographic operation (AES) (FCS_COP.1(2E))
FCS_COP.1.1 The CPACF shall perform encryption and decryption in accordance with a
specified cryptographic algorithm AES in CFB, OFB, CGM, and CBC-CS
modes and cryptographic key sizes 128, 192 or 256 bit that meet the
following: FIPS 197, November 6, 2001 (AES), NIST Special Publication 800-
38A, 2001 Edition (CFB and OFB modes of operation), Addendum to NIST
SP 800-38A, October 2010 (CBC-CS mode of operation), NIST Special
Publication 800-38D (GCM mode of operation).
Application note: This function is provided by the “Cipher Message” and “Cipher
Message with Chaining” instructions. Function Code 18 specifies AES.
A z114 or z196 processor is required in order to use the CPACF for AES
encryption/decryption using AES modes AES-CFB (Cipher Feedback), AES-OFB (Output
Feedback), AES-GCM (Galois/Counter Mode), and AES-CBC-CS (Cipher Block Chaining –
CipherText Stealing)
6.2.3 Cryptographic operation (SHA-1) (FCS_COP.1(3E))
FCS_COP.1.1 The CPACF shall perform hashing in accordance with a specified
cryptographic algorithm SHA-1 and cryptographic key sizes not applicable
that meet the following: FIPS 180-3 (October 2008)
Application note: This function is provided by the “Compute intermediate message
digest” and “Compute last message digest” instructions. Function Code 1 specifies SHA-1.
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6.2.4 Cryptographic operation (SHA-2) (FCS_COP.1(4E))
FCS_COP.1.1 The CPACF shall perform hashing in accordance with a specified
cryptographic algorithms SHA-224, SHA-256, SHA-384, and SHA-512 and
cryptographic key sizes not applicable that meet the following: FIPS 180-3
(October 2008).
Application note: This function is provided by the “Compute intermediate message
digest” and “Compute last message digest” instructions. Function Code 2 specifies SHA-
256. Function Code 3 specifies SHA-512. With appropriate input values and post-
processing, the SHA-256 processing can produce SHA-224 results, and the SHA-512
processing can produce SHA-384 results.
6.3 Security requirements for CEX3 in CEX3C mode
CEX3 in CEX3C mode is a cryptographic coprocessor that provides the ability to perform
both symmetric and asymmetric encryption. The coprocessor can be used via ICSF which
uses the CCA functions to request services from the coprocessor. In the evaluated
configuration only a subset of the functions provided by the coprocessor is used providing
some of the basic encryption functions required by System SSL. The following SFRs therefore
reflect only those functions and not the full set of capabilities of the CEX3C. TSF functions in
the evaluated configuration may use the CEX3C for RSA key generation as well as RSA
encryption and decryption. Both the clear key option (where the private key may be
exported in clear from the coprocessor to the TOE) as well as the secure key option (where
the private key is never exported in clear from ICSF) are supported. The secure key option is
useful in environments where the risk of leakage of the private key from the TOE is viewed
as unacceptable. This allows the TOE to securely use public key cryptography, since the
CEX3C with its physical security protection provide an additional barrier for an attacker.
Although the CEX3C is also capable to perform symmetric encryption operations using DES
and TDES, those functions are not used by the TSF. Performing DES or TDES symmetric
encryption using the CPACF is significantly more efficient than using those functions on the
CEX3C.
6.3.1 Cryptographic operation (RSA) (FCS_COP.1(7E))
FCS_COP.1.1 The CEX3C shall perform encryption and decryption in accordance with a
specified cryptographic algorithm RSA and cryptographic key sizes 1024 to
4096 bit that meet the following: RSA encryption and decryption operation
as defined in PKCS#1 V2.1 (June 14, 2002) using either non-CRT or CRT key
format as defined in section 3.2 of PKCS#1, Version 2.1 (June 14, 2002).
Application note: This function is with both the clear key and the secure key option.
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6.3.2 Cryptographic key generation (Public/Private Keys)
(FCS_CKM.1(2E))
FCS_CKM.1.1 The CEX3C shall generate RSA public/private cryptographic keys in
accordance with a specified cryptographic key generation algorithm vendor
specific and specified cryptographic key sizes between 1024 and 4096 bit
that meet the following: none.
Application note: Keys are either generated as "cleartext keys" where the private key
can be extracted in clear by the system using the CEX3C or they are generated as "secure
keys" where the private key is never exported in clear from the CEX3C.
6.4 Security requirements for CEX3 in CEX3A mode
The CEX3 in CEX3A mode is used as an accelerator card for asymmetric
encryption/decryption operations. It provides the ability for fast RSA encryption and
decryption operations. The coprocessor performs no key generation and does not provide
any key storage capability.
6.4.1 Cryptographic support operation (FCS_COP.1(6E))
FCS_COP.1.1 The CEX3A shall perform long integer modulo operations as support for
encryption and decryption in accordance with a specified cryptographic
algorithm RSA and cryptographic key sizes 1024 to 4096 bit that meet the
following: none
6.5 Additional Security requirements for CryptoExpress 3
(CEX3) on z114 and z196
CryptoExpress 3 (CEX3) operating in CEX3C mode on the z114 and z196 also provides ECC
functionality not provided on the z10. The following SFRs reflect those CEX3 functions used
via ICSF in z/OS R13. For other functions refer to the prior SFRs for CryptoExpress 3.
6.5.1 Cryptographic operation (ECC Digital Signature
Generation) (FCS_COP.1(8E))
FCS_COP.1.1 The CEX3C when operating on the z114 and z196 processors shall
perform digital signature generation with a specified cryptographic
algorithm ECDSA that meet the following: curve parameter shall be one
of 192, 224, 256, 384, or521 bit using the curve parameter defined in
FIPS 186-2, or Brainpool 160, 192, 224, 256, 320, 384, or 512 bit using
the curve parameter defined in RFC5639 (non-twisted curves only); the
hash function shall be one of SHA-1, SHA-224, SHA-256, SHA-384, or SHA-
512 as defined in FIPS 180-3; the signature shall be generated in
accordance with ANSI X9.62-2005, section 7.3.
Application note: This function is with both the clear key and the secure key option.
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6.5.2 Cryptographic operation (ECC Digital Signature
Verification) (FCS_COP.1(9E))
FCS_COP.1.1 The CEX3C when operating on the z114 and z196 processors shall perform
digital signature generation with a specified cryptographic algorithm ECDSA
that meet the following: curve parameter shall be one of 192, 224, 256,
384, or521 bit using the curve parameter defined in FIPS 186-2, or
Brainpool 160, 192, 224, 256, 320, 384, or 512 bit using the curve
parameter defined in RFC5639 (non-twisted curves only); the hash function
shall be one of SHA-1, SHA-224, SHA-256, SHA-384, or SHA-512 as defined
in FIPS 180-3; the signature shall be generated in accordance with ANSI
X9.62-2005, section 7.4.
Application note: This function is with both the clear key and the secure key option.
6.5.3 Cryptographic key generation (ECDSA Public/Private
Keys) (FCS_CKM.1(3E))
FCS_CKM.1.1 The CEX3C when operating on the z114 and z196 processors shall
generate ECDSA public/private cryptographic keys in accordance with a
specified cryptographic key generation algorithm vendor specific and
specified curves one of NIST 192, 224, 256, 384, or521 bit using the curve
parameter defined in FIPS 186-2, or Brainpool 160, 192, 224, 256, 320,
384, or 512 bit using the curve parameter defined in RFC5639 (non-twisted
curves only) that meet the following: ANSI X9.62-2005, Appendix A.4.3.
Application note: Keys are either generated as "clear keys" where the private key can
be extracted in clear by the system using the CEX3C or they are generated as "secure
keys" where the private key never leaves the coprocessor except in an encrypted form.
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7 Security Requirements
7.1 TOE Security Functional Requirements
The following table shows the Security functional requirements for the TOE, and the
operations performed on the components according to CC part 2: iteration (Iter.), refinement
(Ref.), assignment (Ass.) and selection (Sel.).
Security
functional
class
Security functional
requirement
Security
functional
component
Source Operations
Iter. Ref. Ass. Sel.
FAU Security
audit
FAU_GEN.1 Audit data
generation
OSPP No No Yes No
FAU_GEN.2 User identity
association
OSPP No No No No
FAU_SAR.1 Audit review OSPP No No Yes No
FAU_SAR.2 Restricted
audit review
OSPP No No No No
FAU_SAR.3 Selectable
audit review
CC-PART2 No No Yes No
FAU_SEL.1 Selective
audit
OSPP No Yes Yes No
FAU_STG.1 Protected
audit trail storage
OSPP No No No Yes
FAU_STG.3 Action in
case of possible audit
data loss
OSPP No Yes Yes No
FAU_STG.4 Prevention of
audit data loss
OSPP No No Yes Yes
FCS
Cryptographic
support
FCS_CKM.1(SYM)
Cryptographic key
generation: symmetric
algorithms
FCS_CKM.1 OSPP Yes Yes Yes No
FCS_CKM.1(RSA)
Cryptographic key
generation: RSA
FCS_CKM.1 OSPP Yes No Yes No
FCS_CKM.1(DSA) FCS_CKM.1 OSPP Yes No Yes Yes
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Security
functional
class
Security functional
requirement
Security
functional
component
Source Operations
Iter. Ref. Ass. Sel.
Cryptographic key
generation: DSA
FCS_CKM_EXT.1(ECDSA)
Cryptographic key
generation: ECDSA
ST No Yes Yes No
FCS_CKM.2(NET)
Cryptographic key
distribution
FCS_CKM.2 OSPP No Yes Yes Yes
FCS_CKM.4
Cryptographic key
destruction
OSPP No No No Yes
FCS_COP_EXT.1(SGN)
Cryptographic operation:
signatures
ST Yes Yes Yes No
FCS_COP.1(NET)
Cryptographic operation:
network
FCS_COP.1 OSPP No Yes Yes Yes
FCS_COP_EXT.1(CRYPTO-
ENC) Cryptographic
operation: general
purpose
encryption/decryption
ST Yes Yes Yes No
FCS_COP_EXT.1(CRYPTO-
MD) Cryptographic
operation: general
purpose message digest
generation
ST Yes Yes Yes No
FCS_COP_EXT.1(CRYPTO-
SGN) Cryptographic
operation: general
purpose signature
generation and
verification
ST Yes Yes Yes No
FCS_RNG.1 Random
number generation
OSPP No No Yes Yes
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Security
functional
class
Security functional
requirement
Security
functional
component
Source Operations
Iter. Ref. Ass. Sel.
FDP User data
protection
FDP_ACC.1(PSO) Subset
access control:
persistent objects
FDP_ACC.1 OSPP Yes No Yes No
FDP_ACC.1(TSO) Subset
access control: transient
objects
FDP_ACC.1 OSPP Yes No Yes No
FDP_ACF.1(PSO-MVS)
Security attribute based
access control: MVS
FDP_ACF.1 OSPP Yes Yes Yes No
FDP_ACF.1(PSO-UNIX)
Security attribute based
access control: UNIX
FDP_ACF.1 OSPP Yes Yes Yes No
FDP_ACF.1(PSO-LDAP)
Security attribute based
access control: LDAP
FDP_ACF.1 OSPP Yes Yes Yes No
FDP_ACF.1(TSO) Security
attribute based access
control: UNIX IPC
FDP_ACF.1 OSPP Yes Yes Yes No
FDP_ETC.1 (Labeled
Security Mode only)
Export of user data
without security
attributes
CC-PART2 No Yes Yes No
FDP_ETC.2(LS) (Labeled
Security Mode only)
Export of user data with
security attributes
FDP_ETC.2 OSPP-LS No Yes Yes No
FDP_IFC.2(LS) (Labeled
Security Mode only)
Complete information
flow control: labeled
security
FDP_IFC.2 OSPP-LS Yes Yes Yes No
FDP_IFC.2(NI) Complete
information flow control:
network
FDP_IFC.2 OSPP Yes No Yes No
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Security
functional
class
Security functional
requirement
Security
functional
component
Source Operations
Iter. Ref. Ass. Sel.
FDP_IFF.1(NI) Simple
security attributes
FDP_IFF.1 OSPP No No Yes Yes
FDP_IFF.2(LS) (Labeled
Security Mode only)
Hierarchical security
attributes
FDP_IFF.2 OSPP-LS No Yes Yes No
FDP_ITC.1(LS) (Labeled
Security Mode only)
Import of user data
without security
attributes
FDP_ITC.1 OSPP-LS No Yes Yes No
FDP_ITC.2 Import of user
data with security
attributes
OSPP Yes No Yes No
FDP_ITC.2(LS) (Labeled
Security Mode only)
Import of user data with
security attributes:
labeled security
FDP_ITC.2 OSPP-LS Yes Yes Yes No
FDP_RIP.2 Full residual
information protection
OSPP No No No Yes
FDP_RIP.3 Full residual
information protection of
resources
OSPP No No No Yes
FIA
Identification
and
authentication
FIA_AFL.1 Authentication
failure handling
OSPP No Yes Yes Yes
FIA_ATD.1(HU) User
attribute definition:
human users
FIA_ATD.1 OSPP Yes Yes Yes No
FIA_ATD.1(TU) User
attribute definition:
technical users
FIA_ATD.1 OSPP Yes No Yes No
FIA_ATD.1(EIA) User
attribute definition: EIA
FIA_ATD.1 OSPP-EIA Yes No Yes No
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Security
functional
class
Security functional
requirement
Security
functional
component
Source Operations
Iter. Ref. Ass. Sel.
FIA_ATD.1(LS) (Labeled
Security Mode only) User
attribute definition:
labeled security
FIA_ATD.1 OSPP-LS Yes Yes No No
FIA_SOS.1 Verification of
secrets
OSPP No No No No
FIA_UAU.1 Timing of
authentication
OSPP No No Yes No
FIA_UAU.5 Multiple
authentication
mechanisms
OSPP No Yes Yes No
FIA_UAU.7 Protected
authentication feedback
OSPP No No No No
FIA_UAU.8(EIA)
Authentication policy
decisions
FIA_UAU.8 OSPP-EIA No No Yes No
FIA_UID.1 Timing of
identification
OSPP No No Yes No
FIA_UID.3(EIA)
Identification policy
decisions
FIA_UID.3 OSPP-EIA No No Yes No
FIA_USB.1(LS) (Labeled
Security Mode only)
User-subject binding
FIA_USB.1 OSPP-LS No Yes Yes No
FIA_USB.2 Enhanced
user-subject binding
OSPP No Yes Yes No
FMT Security
management
FMT_MSA.1(PSO)
Management of object
security attributes:
persistent objects
FMT_MSA.1 OSPP Yes Yes Yes Yes
FMT_MSA.1(TSO)
Management of object
security attributes:
FMT_MSA.1 OSPP Yes Yes Yes Yes
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Security
functional
class
Security functional
requirement
Security
functional
component
Source Operations
Iter. Ref. Ass. Sel.
transient objects
FMT_MSA.1(LS) (Labeled
Security Mode only)
Management of object
security attributes:
labeled security
FMT_MSA.1 OSPP-LS Yes Yes Yes No
FMT_MSA.3(PSO) Static
attribute initialization:
persistent objects
FMT_MSA.3 OSPP Yes No Yes No
FMT_MSA.3(TSO) Static
attribute initialization:
transient objects
FMT_MSA.3 OSPP Yes No Yes No
FMT_MSA.3(NI) Static
attribute initialization:
network
FMT_MSA.3 OSPP Yes No Yes Yes
FMT_MSA.3(LS) (Labeled
Security Mode only)
Static attribute
initialization: labeled
security
FMT_MSA.3 OSPP-LS Yes Yes Yes No
FMT_MSA.4(PSO)
Security attribute value
inheritance: persistent
objects
FMT_MSA.4 OSPP No No Yes No
FMT_MTD.1(AE)
Management of TSF
data: audit events
FMT_MTD.1 OSPP Yes No Yes No
FMT_MTD.1(AS)
Management of TSF
data: audit storage
FMT_MTD.1 OSPP Yes No Yes Yes
FMT_MTD.1(AT)
Management of TSF
data: audit trail
threshold
FMT_MTD.1 OSPP Yes Yes Yes Yes
FMT_MTD.1(AF) FMT_MTD.1 OSPP Yes Yes Yes Yes
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Security
functional
class
Security functional
requirement
Security
functional
component
Source Operations
Iter. Ref. Ass. Sel.
Management of TSF
data: audit storage
failure
FMT_MTD.1(NI)
Management of TSF
data: network filters
FMT_MTD.1 OSPP Yes No Yes Yes
FMT_MTD.1(NI2)
Management of TSF
data: IPSec
FMT_MTD.1 CC-PART2 Yes No Yes Yes
FMT_MTD.1(IAT)
Management of TSF
data: authentication
threshold
FMT_MTD.1 OSPP Yes No Yes No
FMT_MTD.1(IAF)
Management of TSF
data: account re-
enablement
FMT_MTD.1 OSPP Yes No Yes No
FMT_MTD.1(IAU)
Management of TSF
data: user security
attributes
FMT_MTD.1 OSPP Yes Yes Yes No
FMT_MTD.1(IAU-AUTH)
Management of TSF
data: authentication
data
FMT_MTD.1 OSPP Yes Yes Yes No
FMT_MTD.1(EIA)
Management of TSF
data: EIA
FMT_MTD.1 OSPP-EIA Yes No Yes No
FMT_MTD.1(CRYPTO1)
Management of TSF
data: key import
FMT_MTD.1 CC-PART2 Yes No Yes Yes
FMT_MTD.1(CRYPTO2)
Management of TSF
data: digital certificates
FMT_MTD.1 CC-PART2 Yes No Yes Yes
FMT_MTD.1(ADD) FMT_MTD.1 CC-PART2 Yes Yes Yes Yes
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Security
functional
class
Security functional
requirement
Security
functional
component
Source Operations
Iter. Ref. Ass. Sel.
Management of TSF
data: additional
configuration
FMT_REV.1(OBJ)
Revocation: objects
FMT_REV.1 OSPP Yes No Yes No
FMT_REV.1(USR)
Revocation: users
FMT_REV.1 OSPP Yes No Yes No
FMT_SMF.1 Specification
of Management
Functions
OSPP No No Yes No
FMT_SMR.1 Security
roles
OSPP No No Yes No
FPT Protection
of the TSF
FPT_STM.1 Reliable time
stamps
OSPP No No No No
FPT_TDC.1 Inter-TSF
basic TSF data
consistency
OSPP Yes No Yes No
FPT_TDC.1(LS) (Labeled
Security Mode only)
Inter-TSF basic TSF data
consistency: labeled
security
FPT_TDC.1 OSPP-LS Yes No Yes No
FTA TOE
access
FTA_SSL.1 TSF-initiated
session locking
OSPP No No Yes No
FTA_SSL.2 User-initiated
locking
OSPP No No Yes No
FTP Trusted
path/channels
FTP_ITC.1 Inter-TSF
trusted channel
OSPP No Yes Yes Yes
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Table 6: Security functional requirements for the TOE
7.1.1 Security audit (FAU)
7.1.1.1 Audit data generation (FAU_GEN.1)
FAU_GEN.1.1 The TSF shall be able to generate an audit record of the following
auditable events:
a) Start-up and shutdown of the audit functions;
b) All auditable events for the basic level of audit; and
c) all modifications to the set of events being audited;
d) all user authentication attempts;
e) all denied accesses to objects for which the access control policy
defined in the OSPP base applies;
f) explicit modifications of access rights to objects covered by the
access control policies; and
g) the events listed in Table 7: Auditable Events.
Component Event Details
FAU_GEN.1 Startup and shutdown
of the audit functions.
SMF type 81 record
(RACF initialization).
Note: SMF type 90
record, subtypes 5 and
9, record SMF status.
IFASMFDP and IDCAMS
can be used to report
on these records.
FAU_GEN.2 None.
FAU_SAR.1 Reading of information
from the audit records.
SMF type 80 record for
the raw and saved SMF
data sets.
FAU_SAR.2 Unsuccessful attempts
to read information
from the audit records.
SMF type 80 record,
event code 2 (rejected
attempt to access a raw
SMF data set or a saved
SMF data set).
FAU_SAR.3 None.
FAU_SEL.1 All modifications to the
audit configuration
that occur while the
audit collection
functions are
SMF records generated
by the RACF commands
that modify the audit
configuration (SMF type
90 record, subtypes 5
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Component Event Details
operating. and 9. IFASMFDP and
IDCAMS can be used to
report on these
records).
FAU_STG.1 None.
FAU_STG.3 Actions taken due to
exceeding of a
threshold.
Not applicable due to
implementation. (The
TOE switches
automatically to
another empty data set
once the current data
set used for auditing is
full. The TOE is able to
start a program that is
defined in the audit
configuration to process
the audit records in the
data set that got filled
up.)
FAU_STG.4 Actions taken due to
the audit storage
failure.
The system enters a
wait state.
FCS_CKM.1(SYM) The object attribute(s),
and object value(s)
excluding any
sensitive information
(e.g. secret or private
keys)
None.
FCS_CKM.1(RSA)
FCS_CKM.1(DSA)
FCS_CKM.1(ECDSA)
Cryptographic key
generation
SMF type 80 record,
event code 66 for
RACDCERT command
with the GENREQ
keyword specified
FCS_CKM.2(NET) None.
FCS_CKM.4 None.
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Component Event Details
FCS_COP_EXT.1(SGN) None.
FCS_COP.1(NET) None.
FCS_COP_EXT.1(CRYPT
O-ENC)
None.
FCS_COP_EXT.1(CRYPT
O-MD)
None.
FCS_COP_EXT.1(CRYPT
O-SGN)
None.
FCS_RNG.1 None.
FDP_ACC.1(PSO)
FDP_ACC.1(TSO)
None.
FDP_ACF.1(PSO-MVS) All requests to perform
an operation on an
object covered by the
Security Function
Policy (SFP).
SMF type 80 record,
event code 2 for access
to MVS resources.
FDP_ACF.1(PSO-UNIX)
FDP_ACF.1(TSO)
All requests to perform
an operation on an
object covered by the
Security Function
Policy (SFP).
SMF type 80 record,
event codes 28-30 for
access to UNIX
resources.
FDP_ACF.1(PSO-LDAP) All requests to perform
an operation on an
object covered by the
Security Function
Policy (SFP).
SMF type 83 record,
subtype 3,, event codes
1,3,5,8,9,10 for access
to LDAP LDBM
resources.
FDP_ETC.1(Labeled
Security Mode only)
All attempts to export
information.
SMF type 80 record,
event code 2, for
TAPEVOL class.
FDP_ETC.2(LS)
(Labeled Security
Mode only)
All attempts to export
information.
SMF type 80 record,
event code 2, for
TAPEVOL class.
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Component Event Details
FDP_ETC.2(LS)
(Labeled Security
Mode only)
Overriding of human-
readable output
marking. (Additional)
SMF type 80 record,
event code 2, for
PSFMPL class.
FDP_IFC.2(LS)(Labeled
Security Mode only)
None.
FDP_IFC.2(NI) None.
FDP_IFF.1(NI) All permitted traffic, all
denied traffic not
silently discarded
All traffic logged with
syslog. Rules explicitly
discarding packets will
not generate a syslog
record.
FDP_IFF.2(LS)(Labeled
Security Mode only)
All decisions on
requests for
information flow.
SMF type 80 record,
event code 2, with
reason indicating
SECLABEL AUDIT.
FDP_ITC.1(LS)(Labeled
Security Mode only)
All attempts to import
user data, including
any security attributes.
SMF type 80 record,
event code 2,
associated with
TAPEVOL profiles.
FDP_ITC.2
FDP_ITC.2(LS)(Labeled
Security Mode only)
All attempts to import
user data, including
any security attributes.
SMF type 80, event
code 2, associated with
TAPEVOL profiles.
FDP_RIP.2 None.
FDP_RIP.3 None.
FIA_AFL.1 Authentication failure
notification and
account locking.
SMF type 80 record,
event code 1, all
qualifiers except 0, 12
and 13. Qualifier 7
especially reports
account locking.
FIA_ATD.1(HU),
FIA_ATD.1(TU),
FIA_ATD.1(EIA),
FIA_ATD.1(LS)(Labeled
None.
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Component Event Details
Security Mode only)
FIA_SOS.1 Rejection or
acceptance by the TSF
of any tested secret.
SMF type 80 record,
event code 1, qualifier 1
(password/phrase not
valid).
Also SMF type 80, event
code 68, qualifier 0
(success) or 1 (failure)
to generate a Kerberos
TGT
Also SMF type 80, event
code 70, qualifier 2 for
R_PKIServ Export
function with incorrect
passphrase.
FIA_UAU.1
FIA_UAU.8(EIA)
All use of the
authentication
mechanism.
SMF type 80 record,
event code 1, various
qualifiers and SMF
record type 30 subtypes
1 and 5).
Also SMF type 80, event
code 68, qualifier 0
(success) or 1 (failure)
to generate a Kerberos
TGT
Also SMF type 83,
subtype 3, event codes
2,4,6,11 for LDAP bind
operations.
FIA_UAU.5 None specific. All
authentication
functions produce the
audit records
mentioned for
FIA_UAU.1 and
FIA_UID.1
FIA_UAU.7 None.
FIA_UID.1 All use of the user SMF type 80 record,
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Component Event Details
identification
mechanism, including
the identity provided
during successful
attempts.
event code 1, various
qualifiers. Also, SMF
type 30 record.
FIA_UID.3(EIA) All use of the user
identification
mechanism, including
the identity provided
during successful
attempts.
SMF type 80 record,
event code 1, various
qualifiers. Also, SMF
type 30 record.
FIA_USB.1(LS)(Labeled
Security Mode only)
FIA_USB.2
Success and failure of
binding user security
attributes to a subject
(e.g. success and
failure to create a
subject).
SMF type 80 record,
event code 1, various
qualifiers. Also, SMF
type 30 record,
subtypes 1 and 5.
FMT_MSA.1(PSO)
FMT_MSA.1(TSO)
FMT_MSA.1(LS)
(Labeled Security
Mode only)
All modifications of the
values of security
attributes.
SMF type 80 record
(generated by the RACF
commands).
FMT_MSA.3(PSO)
FMT_MSA.3(TSO)
FMT_MSA.3(LS)
(Labeled Security
Mode only)
Modifications of the
default setting of
permissive or
restrictive rules. All
modifications of the
initial value of security
attributes.
SMF type 80 record
(generated by the RACF
commands).
FMT_MSA.4(PSO) None.
FMT_MTD.1(AE)
FMT_MTD.1(AF)
FMT_MTD.1(AS)
FMT_MTD.1(AT)
All modifications to the
values of TSF data.
SMF type 80 record
(generated by the RACF
commands).
FMT_MTD.1(NI)
FMT_MSA.3(NI)
All modifications of TSF
data (Management of
SMF type 80 record
generated by access
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Component Event Details
IPSec, IP filtering, and
Defensive Filtering
configuration from the
command line)
check to SERVAUTH
resource that controls
ability to use this
administrative interface.
FMT_MTD.1(NI2) All modifications of TSF
data
(Management of IPSec
via network interfaces)
SMF type 80 record
generated by access
check to SERVAUTH
resource that controls
ability to use this
administrative interface
FMT_MTD.1(IAU)
FMT_MTD.1(IAU-AUTH)
FMT_MTD.1(IAF)
FMT_MTD.1(IAT)
FMT_MTD.1(EIA)
All modifications to the
values of TSF data.
SMF type 80 record
(generated by the RACF
commands).
FMT_MTD.1(CRYPTO1) All modifications to the
values of TSF data
SMF type 80 record
(generated by the RACF
command RACDCERT).
FMT_MTD.1(CRYPTO2) All modifications of TSF
data (Management
activities related to PKI
services)
auditing performed by
PKI Services.:
SMF Type 80.
Event code 72 : Cert
admin READ record
Event code 73 : Cert
admin Update request
record
Event code 74 : Cert
admin Update
certificate record
Event code 79 : CRL
Publication
Event code 80 : PKI
response for cert status
Event code 83 : SCEP
request
FMT_MTD.1(ADD) All modifications of TSF SMF Type 80 records
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Component Event Details
data
(Management
activities related to
other TOE
configuration data)
associated with access
checks for access to
MVS data sets, UNIX
files, or LDAP objects
holding the
configuration data.
FMT_REV.1(USR) All attempts to revoke
security attributes.
SMF type 80 record
(generated by the RACF
commands).
FMT_REV.1(OBJ) All attempts to revoke
security attributes.
SMF type 80 record
(generated by the RACF
commands).
FMT_SMF.1 None specifically
associated with this
SFR, but auditing is
covered under the
FMT_MSA.1,
FMT_MSA.3,
FMT_MTD.1,
FMT_REV.1,
FAU_SAR.1, FAU_SEL.1,
FAU_STG.3,
FAU_STG.4, and
FMT_SMR.1
requirements which
are implied by
FMT_SMF.1 as
discussed in chapter 8.
FMT_SMR.1 Modifications to the
group of users that are
part of a role.
SMF type 80 record
(generated by the RACF
commands).
FMT_SMR.1 Every use of the rights
of a role. (Additional /
Detailed)
SMF type 80 record.
FPT_STM.1 Changes to the time. SMF type 80 record for
MVS™ operator
command SET CLOCK.
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Component Event Details
FPT_TDC.1
FPT_TDC.1(LS)
(Labeled Security
Mode only)
None
FTA_SSL.1
FTA_SSL.2
None
FTP_ITC.1 None
Table 7: Auditable Events
FAU_GEN.1.2 The TSF shall record within each audit record at least the following
information:
a) Date and time of the event, type of event, subject identity (if
applicable), and outcome of the event; and
b) For each audit event type, based on the auditable event definitions
of the functional components included in the PP/ST;
i. User identity (if applicable); and
ii. (in Labeled Security Mode) The sensitivity labels of
subjects, objects, or information involved; and
iii. The additional information specified in the “Details”
column of Table 7: Auditable Events.
Application note: Each SMF record has a standard header that includes
the ID of the job that caused the event. The ID of the job is related to the
user ID under which the job has been started by SMF. Users accessing the
HTTP server or LDAP server without authenticating themselves are audited
with the user ID the server is configured to use for unauthenticated users.
Also, for the HTTP server, authenticated users running under an
administrator-configured ID for data access are audited with that
administrator-configured ID. Also, in some cases of client authentication
via SSL, when RACF certificate mapping rules are used to assign an
administrator-specified ID rather than a unique ID, the audit records will
contain the administrator-specified ID and the X500-based distinguished
name from the client’s digital certificate for accountability purposes.
7.1.1.2 User identity association (FAU_GEN.2)
FAU_GEN.2.1 For audit events resulting from actions of identified users, the TSF shall be
able to associate each auditable event with the identity of the user that
caused the event.
7.1.1.3 Audit review (FAU_SAR.1)
FAU_SAR.1.1 The TSF shall provide the authorized administrators with the capability
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to read all audit information from the audit records.
FAU_SAR.1.2 The TSF shall provide the audit records in a manner suitable for the user to
interpret the information.
Application note: In this case, the term "authorized administrators" maps to the AUDITOR
role of z/OS or a user with SPECIAL.
7.1.1.4 Restricted audit review (FAU_SAR.2)
FAU_SAR.2.1 The TSF shall prohibit all users read access to the audit records, except
those users that have been granted explicit read-access.
7.1.1.5 Selectable audit review (FAU_SAR.3)
FAU_SAR.3.1 The TSF shall provide the ability to apply searches of audit data based on
the following attributes:
a) user identity;
b) subject sensitivity label; (Labeled Security Mode only)
c) object sensitivity label; (Labeled Security Mode only)
d) object type and object name
7.1.1.6 Selective audit (FAU_SEL.1)
FAU_SEL.1.1 The TSF shall be able to select the set of events to be audited from the set
of all auditable events based on the following attributes:
a) Type of audit event;
b) Subject or user identity;
c) Outcome (success or failure) of the audit event;
d) Named object identity;
e) subject sensitivity label; (Labeled Security Mode only);
f) object sensitivity label; (Labeled Security Mode only)
Application note: RACF allows inclusion of auditable events based on the criteria defined
above.
7.1.1.7 Protected audit trail storage (FAU_STG.1)
FAU_STG.1.1 The TSF shall protect the stored audit records in the audit trail from
unauthorized deletion.
FAU_STG.1.2 The TSF shall be able to prevent unauthorized modifications to the audit
records in the audit trail.
Application note: RACF data set protection needs to be used to protect the files
containing audit records from unauthorized access and modification.
7.1.1.8 Action in case of possible audit data loss (FAU_STG.3)
FAU_STG.3.1 The TSF shall generate an alarm to the z/OS operator if the audit trail
exceeds the capacity of the current SMF data set. or if any of the
following list of conditions is detected that may result in a loss of audit
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records.
Application note: The TOE switches to the next available SMF data set. Saving the SMF
data set that got filled up can be done automatically or manually.
7.1.1.9 Prevention of audit data loss (FAU_STG.4)
FAU_STG.4.1 The TSF shall prevent audited events, except those taken by the
authorized administrator and inform a z/OS operator if the audit trail
is full.
7.1.2 Cryptographic support (FCS)
7.1.2.1 Cryptographic key generation: symmetric algorithms
(FCS_CKM.1(SYM))
FCS_CKM.1.1 The TSF shall generate symmetric cryptographic keys in
accordance with a specified cryptographic key generation
algorithm capable of generating a random bit sequence and
specified cryptographic key sizes:
a) 128 bits (TLS/SSL: AES; IPSec: AES; SSH: AES; Kerberos:
AES)
b) 168 bits (TLS/SSL: TDES; IPSec: TDES; SSH: TDES;
Kerberos: TDES)
c) 192 bits (SSH: AES)
d) 256 bits (TLS/SSL: AES; IPSec: AES; SSH: AES; Kerberos:
AES)
that meet the following:
keys are generated based on a random number generator
which ensures an entropy that is at least as high as the
size of the key and which satisfies the following (based on
the use of the key material in cryptographic protocols):
a) TLS/SSL: generation and exchange of session keys
as defined in the SSLv3 [SSLV3] ,TLSv1 [TLSV1],
and TLSv1.1 [TLSV1.1] standards with the cipher
suites defined in FCS_COP.1(NET)
b) IPSec: FIPS 46-3,FIPS 197 as defined in RFC4109,
RFC5996, RFC2308, and RFC4835.
c) SSH: generation and exchange of session keys
using the Diffie-Hellman key negotiation protocol as
defined in RFC4253
d) Kerberos: generation and exchange of TDES, or AES
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session keys as defined in the Kerberos v5
standards (RFC1510, RFC3961, and RFC3962).
Application note: For details of the SSH key generation and key negotiation process see
section 8 of [RFC4253]. The evaluation will assess that the keys are generated in
accordance with the requirements defined in [RFC4253].
7.1.2.2 Cryptographic key generation: RSA (FCS_CKM.1(RSA))
FCS_CKM.1.1 The TSF shall generate RSA cryptographic keys in accordance
with a specified cryptographic key generation algorithm defined
in U.S. NIST FIPS PUB 186-3 appendix B.3 and specified
cryptographic key sizes:
a) 2048 bits
b) 1024 bits, 4096 bits
that meet the following:
a) U.S. NIST FIPS PUB 186-3,
b) generation of SSH host keys as defined in the
Secure Shell (SSH) Transport Layer Protocol,
RFC4253.
Application Note: This SFR addresses the RSA key generation in ICSF and Ported Tools
(OpenSSH). The reference to RFC4253 applies to the RSA key generation in Ported Tools
only.
Application note: For SSH keys, this requirement addresses the generation of
public/private keys for host authentication, i.e., using the ssh-keygen utility. Exchange of
the public keys generated involves a manual process of the administrator making the
public key file available to the client users, and the client users copying those key files.
ssh has not been modified from the Open Source version with respect to the
cryptographic functions used and will therefore always use the software functions of the
OpenSSL library for key generation and cryptographic operations.
7.1.2.3 Cryptographic key generation: DSA (FCS_CKM.1(DSA))
FCS_CKM.1.1 The TSF shall generate DSA cryptographic keys in accordance
with a specified cryptographic key generation algorithm defined
in U.S. NIST FIPS PUB 186-3 appendix B.1 and specified
cryptographic key sizes:
a) L=1024, N=160 bits;
b) DSA domain parameter generation for specified
values for L and N;
that meet the following:
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a) U.S. NIST FIPS PUB 186-3,
b) generation of SSH host keys as defined in the
Secure Shell (SSH) Transport Layer Protocol,
RFC4253.
Application Note: This SFR addresses the DSA key generation in ICSF and Ported Tools
(OpenSSH). The reference to RFC4253 applies to the DSA key generation in Ported Tools
only.
Application note: Public/private key pairs for X.509v3 certificates can be generated in
software with DSA keys up to 1024 bits. For SSH, the default key length for DSA keys
generated by the ssh-keygen utility is 1024 bits. Please see also the application notes for
FCS_CKM.1(RSA)
7.1.2.4 Cryptographic key generation with platform support:
ECDSA (ECDH) (FCS_CKM_EXT.1(ECDSA))
FCS_CKM_EXT.1.1 The TSF shall generate ECDSA cryptographic keys in accordance
with a specified cryptographic key generation algorithm defined
in Elliptic Curve Digital Signature Algorithm (ECDSA)
specified in FIPS 186-2 with Change Notice 1 dated
October 5, 2001, Digital Signature Standard (DSS), and
specified in ANSI X9.62-2005, Public Key Cryptography for
the Financial Services Industry: The Elliptic Curve Digital
Signature Algorithm (ECDSA) and specified curves:
a) curve parameter shall be one of 192, 224,
256, 384, or521 bit using the curve
parameter defined in FIPS 186-2, or Brainpool
160, 192, 224, 256, 320, 384, or 512 bit using
the curve parameter for non-twisted curves
defined in RFC5639;
and specified cryptographic key sizes [assignment:
cryptographic key sizes]
that meet the following:
a) Elliptic Curve Digital Signature Algorithm
(ECDSA) specified in FIPS 186-2 with Change
Notice 1 dated October 5, 2001, Digital
Signature Standard (DSS), and specified in
ANSI X9.62-2005, Public Key Cryptography
for the Financial Services Industry: The
Elliptic Curve Digital Signature Algorithm
(ECDSA)
using the following support from the underlying platform: for a
TOE executing on a z114 or z196 processor and for TSF
modules that use ICSF, use the ECDSA key pair generated
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by a CryptoExpress3 coprocessor if such a coprocessor is
installed and accessible.
7.1.2.5 Cryptographic key distribution (FCS_CKM.2(NET))
FCS_CKM.2.1 The TSF shall distribute cryptographic keys in accordance with the
following specified cryptographic key distribution method that meets the
following:
a) RSA, DSA, and ECDSA (ECDH) public keys: digital
certificates for public RSA, DSA, and ECDSA (ECDH) keys
that meet the following: certificate format as defined in the
standard X.509 Version 3;
b) TLS/SSL handshake: RSA encrypted exchange of session
keys according to [SSLV3], [TLSV1], and [TLSV1.1];
c) TLS handshake: EC Diffie-Hellman key exchange of session
keys according to [TLSSEC].
d) IPSec: Diffie-Hellman key agreement method defined for
the IKE protocol by RFC2409, RFC4753, and RFC4754;
e) SSH symmetric session keys: Diffie-Hellman key agreement
method defined for the SSH protocol by RFC4253;
f) Kerberos: Kerberos v5 key distribution as defined by
RFC3961.
Application note: This requirement addresses the exchange of public RSA, DSA, and
ECDSA (ECDH) keys during SSL/TLS or IPSec session negotiation, or as distributed within
X509.v3 digital certificates distributed via the CA functions in PKI Services. In TOE
configurations that include CryptoExpress3 (CEX3) in C3X3C mode , RSA public/private
key pairs may be generated by the coprocessor in a form where the private key is never
exported in cleartext. This case is covered by a specific security functional requirement
for the IT environment. The administrator who generates the RSA or ECDSA (ECDH) key
pair can specify in the RACDCERT command used for this key generation, if the key pair is
generated by a cryptographic coprocessor (as part of the IT environment) or by the TOE
itself. The requirement here does not cover this case but only the case where the key pair
is generated by the TSF software (which is always the case for DSA key pairs generated
by the TOE). The public/private key pair may also be generated external to the TOE or
CEX3 cryptographic coprocessor attached to the TOE, and in this case it needs to be
imported using appropriate protection measures as defined in FDP_ITC.1. This SFR
addresses only the RSA, DSA, and ECDSA (ECDH) key pair generation in software within
the TOE. RSA or ECDSA (ECDH) key pair generation by the CEX3 coprocessor is addressed
by SFRs for that components in the IT environment.
Application note: This requirement addresses the exchange of TLS/SSL session keys as
part of the TLS/SSL handshake protocol.
Application note: This requirement addresses the negotiation of session keys as defined
in the IKE standard. The Diffie-Hellman public/private key pair is generated external to the
TOE and needs to be imported using appropriate protection measures as defined in
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FDP_ITC.1.
Application Note: Only the NIST curves P-192 (secp192r1), P-224 (secp224r1), P-256
(secp256r1), P-384 (secp384r1), and P-521 (secp521r1) of [TLSSEC] are supported for
ECDH in the TLS handshake.
7.1.2.6 Cryptographic key destruction (FCS_CKM.4)
FCS_CKM.4.1 The TSF shall destroy cryptographic keys in accordance with a specified
cryptographic key destruction method of zeroization that meets the
following: vendor-specific zeroization.
Application note: Cryptographic session keys for the SSL/TLS, Kerberos, SSH, and IPsec
sessions are protected by the TOE against unauthorized access and are destroyed by the
object re-use functions of the TOE. Long-living private keys of a public/private key pair will
also be destroyed by the object reuse function of the TOE when they are kept in memory.
7.1.2.7 Cryptographic operation with platform support: signatures
(FCS_COP_EXT.1(SGN))
FCS_COP_EXT.1.1 The TSF shall perform digital signature generation and digital
signature verification in accordance with a the specified
cryptographic algorithms DSA, RSA, and ECDSA and cryptographic
key sizes as defined below that meet the following:
a) DSA with L=1024, N=160 bits as defined in FIPS 186-3
b) RSA with 1024bit, 2048 bit, and 4096 bit as defined in
PKCS#1 V2.1 (June 14, 2002)
c) ECDSA with curves as defined in
FCS_CKM_EXT.1(ECDSA) following ANSI X9.62-2005
sections 7.3 and 7.4.
and the requirements for the following protocols: [SSLV3],
[TLSV1], [TLSV1.1], [TLSSEC], Internet Security Association
and Key Management Protocol (ISAKMP) RFC2408.
using the following support from the underlying platform: when a
CEX3C coprocessor is attached to the hardware the TOE is
operating upon and ICSF is installed and operational as
required in the evaluated configuration, System SSL and IPSec
will use this hardware for RSA encryption and decryption
operations.
Application note: This requirement addresses the RSA, DSA, and ECDSA digital
signature generation and verification operations using the RSA, DSA, or ECDSA algorithm
as required by the SSL session establishment protocol (provided a cipher suite including
RSA, DSA, or EC Diffie-Hellman is used), the IPSec ISAKMP session establishment protocol,
and digital certificate generation by RACDCERT (RACF) and PKI Services. The details of the
signature format, such as the use of the PKCS#1 block type 1 and block type 2, are
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defined in the SSLv3 , TLSv1, and TLSv1.1 standards ([SSLV3], [TLSV1], [TLSV1.1]). Note
that for ISAKMP v1 (IKEv1, RFC2408) z/OS supports only RSA as a signature algorithm,
though in IKEv2 (RFC5996, RFC4754) both RSA and ECDSA are supported.
Application Note: Only the NIST curves P-192 (secp192r1), P-224 (secp224r1), P-256
(secp256r1), P-384 (secp384r1), and P-521 (secp521r1) of [TLSSEC] are supported for
TLS.
7.1.2.8 Cryptographic operation: network (FCS_COP.1(NET))
FCS_COP.1.1 The TSF shall perform encryption, decryption, integrity verification, peer
authentication in accordance with the following cryptographic algorithms ,
cryptographic key sizes and applicable standards:
a) SSH allowing the use of TDES in CBC mode with 168 bits key
size, and HMAC-SHA1 defined by RFC 4253 (cipher suite:
3des-cbc);
b) SSH allowing the use of AES in CBC and CTR mode with 128
bits, 192 bits and 256 bits key size, and HMAC-SHA1 defined
by RFC 4253 (cipher suites: aes128-cbc, aes192-cbc,
aes256-cbc, aes128-ctr, aes192-ctr, or aes256-ctr);
c) TLS allowing the use of TDES in CBC mode with 168 bits key
size, and HMAC-SHA-1 defined by RFC4346 (cipher suite
TLS_RSA_3DES_EDE_CBC_SHA as defined in the TLSv1
standard [TLSV1] , [TLSV1.1] and RFC3268);
d) TLS allowing the use of AES in CBC mode with 128 bits and
256 bits key size, and HMAC-SHA-1 defined by RFC4346
(cipher suite TLS_RSA_WITH_AES_128_CBC_SHA and
TLS_RSA_WITH_AES_256_CBC_SHA as defined in the TLSv1
standard [TLSV1] , [TLSV1.1] and RFC3268);
e) SSLv3 allowing the use of TDES with 168 bits key size , and
HMAC-SHA-1 (cipher suite SSL_RSA_TDES_168_SHA as
defined in the SSLv3 standard [SSLV3]);
f) SSLv3 allowing the use of AES in CBC mode with 128 bits
and 256 bits key size, and HMAC-SHA-1 (cipher suite
SSL_RSA_WITH_AES_128_CBC_SHA and
SSL_RSA_WITH_AES_256_CBC_SHA equivalent to ciphers
defined in RFC3268);
g) TLS allowing the use of TDES in CBC mode with 168 bits key
size and SHA-1 defined by [TLSSEC] (cipher suite
TLS_ECDH_ECDSA_WITH_3DES_EDE_CBC_SHA,
TLS_ECDHE_ECDSA_WITH_3DES_EDE_CBC_SHA,
TLS_ECDH_RSA_WITH_3DES_EDE_CBC_SHA,
TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA as defined in
standard [TLSSEC]);
h) TLS allowing the use of AES in CBC mode with 128-bits and
256-bits key size and SHA-1 defined by [TLSSEC] (cipher
suite TLS_ECDH_ECDSA_WITH_AES_128_CBC_SHA,
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TLS_ECDH_ECDSA_WITH_AES_256_CBC_SHA,
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA,
TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA,
TLS_ECDH_RSA_WITH_AES_128_CBC_SHA,
TLS_ECDH_RSA_WITH_AES_256_CBC_SHA,
TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA,
TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA as defined in
standard [TLSSEC].
i) IPSec with IKE allowing the use of AES in CBC mode with 128
bits or 256 bits key size, and either SHA-1, SHA-2,
AES_GMAC or AES_XCBC_MAC_96 as defined by RFC4301,
RFC4303, RFC3602, RFC4106, RFC2404, and RFC4868;
j) IPSec allowing the use of HMAC-SHA-1 for message
authentication, cryptographically securing the payload and
the authentication header of an IP packet as defined in IETF
RFC4303 (IP Encapsulating Security Payload [ESP]) and IETF
RFC4302 (IP Authentication Header) using the specific
method for HMAC-SHA-1 as defined in IETF RFC2404 (The
Use of HMAC-SHA-1-96 within ESP and AH);
k) IPSec allowing the use of AES in GCM mode with 128 bits
and 256 bits key size for combined encryption and
authentication as defined by RFC4301, RFC4303, RFC3602,
RFC4106, RFC2404, and RFC4868;
l) Kerberos allowing TDES or AES with 168 bit (TDES), 128-bit
(AES) or 256-bit (AES) for Encryption and Checksum
specifications as defined in RFC3961 and RFC4537.
Application Note: For potential hardware support in the implementation of the individual
cryptographic algorithms see the SFRs that specify the algorithms. Except for SSH, the
networking functions of the TOE use ICSF functions or CPACF for the basic cryptographic
algorithms.
Application note: SSH always uses the OpenSSL library and the software
implementation of those algorithms in this library.
Application Note: Only the NIST curves P-192 (secp192r1), P-224 (secp224r1), P-256
(secp256r1), P-384 (secp384r1), and P-521 (secp521r1) of TLSSEC are supported for TLS.
7.1.2.9 Cryptographic Operation with platform support
(FCS_COP_EXT.1 (CRYPTO-ENC))
FCS_COP_EXT.1.1 The TSF shall perform encryption and decryption in accordance
with a the following specified cryptographic algorithms TDES, AES,
and RSA and cryptographic key sizes as defined below that meet
the following:
a) TDES with CBC mode of operation and with 168 bits key
size as defined by NIST Special Publication 800-67 (for TDES)
and NIST Special Publication 800-38A, 2001 Edition (for the
CBC mode of operation);
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b) AES with the block chaining modes CBC and GCM
and with the key sizes 128 and 256 bit as defined by FIPS
PUB 197, November 26, 2001 (for AES), NIST Special
Publication 800-38A, 2001 Edition (for the CBC mode of
operation), and NIST Special Publication 800-38D, November
2007 (for the GCM mode of operation);
c) RSA with the key size 4096 bit as defined by PKCS #1
v1.5;
using the following support functionality provided by the underlying
platform:
a) CPACF for the implementation of the TDES and AES
algorithms as specified in [ZARCH]
b) CryptoExpress3 (if installed, configured as
coprocessor and accessible) for the implementation of
the RSA algorithm when the ICSF functions
CSFPPKS/CSFPPKV6 for RSA private key decryption,
CSFPPKV/CSFPPKV6 for RSA public key encryption are
invoked
c) CryptoExpress3 (if installed, configured as accelerator
and accessible) for the implementation of the long
integer modulo operations when the ICSF functions
PKA Encrypt and PKA Decrypt are invoked.
d) CryptoExpress3 (if installed, configured as
coprocessor and accessible and no CryproExpress3
configured as accelerator is available) for the
implementation of the long integer modulo operations
when the ICSF functions PKA Encrypt and PKA Decrypt
are invoked.
Application Note: The ICSF functions PKA Encrypt and PKA decrypt
will fail if no CryptoExpress3 is installed and available. They will not
fall back to a software implementation of the RSA algorithm. The
services will also fail when the caller requests the operation using
encrypted private keys and no CryptoExpress3 configured as
coprocessor is installed and available.
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7.1.2.10 Cryptographic Operation with platform support
(FCS_COP_EXT.1 (CRYPTO-MD))
FCS_COP_EXT.1.1 The TSF shall perform message digest generation in accordance
with a the specified cryptographic algorithms SHA-1, SHA-256,
and SHA-512 and cryptographic keys sizes not applicable that
meet the following:
a) SHA-1 as defined by FIPS PUB 180-3;
b) SHA-256 as defined by FIPS PUB 180-3;
c) SHA-512 as defined by FIPS PUB 180-3;
using the following support functionality provided by the underlying
platform:
a) CPACF for the implementation of the SHA-1, SHA-256
and SHA-512 algorithms as specified in [ZARCH]
Application Note: The PKCS#11 interfaces CSFPOWH/CSFPOWH6
(when called for one-way hash service) provided by ICSF satisfy this
claim.
7.1.2.11 Cryptographic Operation with platform support
(FCS_COP_EXT.1 (CRYPTO-SGN))
FCS_COP_EXT.1.1 The TSF shall perform signature generation and verification in
accordance with a the specified cryptographic algorithms DSA,
RSA, and ECDSA and cryptographic key sizes as defined below that
meet the following:
a) DSA with the following key sizes:
i. L=1024, N=160 bits,
as defined by FIPS PUB 186-3;
b) RSA with the following key sizes:
i. 1024, 2048, 4096 bits,
as defined by FIPS PUB 186-3;
c) ECDSA with the following key sizes:
i. NIST curve=192
ii. NIST curve=224
iii. NIST curve=256
iv. NIST curve=384
v. NIST curve-521
as defined in FIPS 186-3 , Digital Signature Standard (DSS),
and specified in ANSI X9.62-1998, Public Key Cryptography
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for the Financial Services Industry: The Elliptic Curve Digital
Signature Algorithm (ECDSA)
using the following support from the underlying platform:
a) CryptoExpress3 (when installed, configured as
coprocessor and accessible) for RSA and on z114 and
z196 also for ECDSA.
Application Note: The PKCS#11 interfaces CSFPOWH/CSFPOWH6 (when invoked for sign
or verify services), CSFPPKS/CSFPPKS6 (private key sign), and CSFPPKV/CSFPPKV6 (public
key verify) provided by ICSF satisfy this claim. Note that the functions
CSFPOWH/CSFPOWH6 when invoked for signing or verification also perform the generation
of the hash value using one of the algorithms specified in FCS_COP_ES.1 (CRYPTO-MD),
using the support of CPACF for the calculation of the hash value as defined in the SFR
FCS_COP_ES.1 (CRYPTO-MD).
7.1.2.12 Random number generation (FCS_RNG.1)
FCS_RNG.1.1 The TSF shall provide a deterministic random number generator that
implements: forward secrecy and backward secrecy.
FCS_RNG.1.2 The TSF shall provide random numbers that meet the requirements of
functionality class K3 for a medium strength of function as
defined in [AIS20].
7.1.3 User data protection (FDP)
7.1.3.1 Subset access control: persistent objects
(FDP_ACC.1(PSO))
FDP_ACC.1.1 The TSF shall enforce the Persistent Storage Object Access Control Policy
on
a) jobs, started tasks, UNIX processes (whether initiated by
rlogin, telnet, HTTP, FTP, or other method), and TSO
sessions acting on behalf of users
b) Objects: Persistent Storage Objects of the following type
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MVS objects:
data sets, terminals, devices, volumes, consoles,
operator commands, programs, System Logger
objects, Communications Server Policy Agent data;
UNIX objects:
z/OS UNIX file system objects (regular files,
directories and symbolic links, character special files,
UNIX domain sockets and named pipes (FIFOs);
LDAP objects:
LDAP LDBM objects;
c) Operations: all operations among subjects and objects
covered by the Persistent Storage Object Access Control
Policy.
Application note: A persistent storage object establishes a data storage or data
exchange link between two or more subjects. Examples of persistent storage objects are:
files, directories.
7.1.3.2 Subset access control: transient objects (FDP_ACC.1(TSO))
FDP_ACC.1.1 The TSF shall enforce the Transient Storage Object Access Control Policy
on
a) jobs, started tasks, UNIX processes (whether initiated by
rlogin, telnet, HTTP, FTP, or other method), and TSO
sessions acting on behalf of users
b) Objects: Transient Storage Objects of the following type
z/OS UNIX IPC objects:
shared memory segments, message queues,
semaphores
TCP/IP connections;
c) Operations: all operations among subjects and objects
covered by the Transient Storage Object Access Control
Policy.
Application note: A transient storage object establishes a data exchange link between
two or more subjects or users. Examples of transient storage objects are: shared memory,
semaphores, message queues, named/unnamed pipes.
7.1.3.3 Security attribute based access control: MVS
(FDP_ACF.1(PSO-MVS))
FDP_ACF.1.1 The TSF shall enforce the Persistent Storage Object Access Control Policy
to MVS objects based on the following:
a) The user identity and group memberships associated with a
subject; and
b) The following access control attributes associated with an
object:
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i. an access control list capable of defining the access
rights read, update, execute, alter, control, and none
for individual users and groups
ii. a default access right (defined by the UACC attribute
in the resource profile) for users who are not
addressed in the access control list
iii. an entry for the resource containing the object in the
global access checking table.
Application note: The semantics of "read", "update", "execute", "alter",
and "control" are defined by the resource manager and follow the intuitive
semantics of those terms. In the case of the Communications Server Policy
Agent data, the resource manager implements only "read" access to this
data.
Any access right hierarchical to read for the profile protecting this data
will therefore still result only in read access to this data. In the case of
Operator Commands, the semantics of the different access rights is
defined as part of the description of the command.
FDP_ACF.1.2 The TSF shall enforce the following rules to determine if an operation
among controlled subjects and controlled objects is allowed: a subject
has the requested type of access to a protected resource, if the
resource is protected by RACF and
a) if access is allowed by global access checking (Note: does
not apply for user with the RESTRICTED attribute; does not
apply to checks performed by RACROUTE
REQUEST=FASTAUTH)
or, if a) is not true,
b) (in Labeled Security Mode) if the access is not denied by
the mandatory access control
if a) did not grant access, and b) did not deny access,
c) if the resource is a tape or DASD data set and the high-level
qualifier of the data set name is identical to the user ID
if c) did not grant access,
d) if the requested type of access is allowed by an access
control list (ACL) td for this particular user (Note: does not
apply to checks performed by RACROUTE
REQUEST=FASTAUTH with the AUTHCHKS=CRITONLY
option)
if d) neither granted nor denied access then continue with e)
Otherwise, if d) denied access, continue with h),
e) if the requested type of access is allowed by an ACL entry
for the group the user belongs to. If list-of-groups
processing is not in effect, this rule is evaluated only for
the current connect group. Otherwise, this rule is evaluated
for all groups to which the user is connected. (Note: does
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not apply to checks performed by RACROUTE
REQUEST=FASTAUTH with the AUTHCHKS=CRITONLY
option)
if no entries in e) granted access, and no entries in e) denied
access, then continue with f). Otherwise, if at least one td in e)
denied access, then continue with h),
f) if the user does not have the RESTRICTED attribute and the
requested type of access is granted by the universal access
authority (UACC) in the profile protecting the resource or
granted by an ACL with ID(*)(Note: does not apply to checks
performed by RACROUTE REQUEST=FASTAUTH with the
AUTHCHKS=CRITONLY option)
if f) did not grant access,
g) if the user has the OPERATIONS role or the group-
OPERATIONS role (for a group to which the user is
connected and the resource is within the group’s scope)
and OPERATIONS access is allowed for the class
if g) did not grant access,
h) if the user has an td in the conditional access list for the
profile that allows the requested type of access and the
user meets the condition defined in this conditional access
list td (Note: for checks performed by RACROUTE
REQUEST=FASTAUTH with the AUTHCHKS=CRITONLY
option, only conditional access list entries specifying
WHEN(CRITERIA(SQLROLE…)) will apply)
or, if h) did not grant access,
i) if the user is a member of a group that has an td in the
conditional access list for the profile that allows the
requested type of access and the user meets the condition
defined in this conditional access list td. If list-of-groups
processing is not in effect, this rule is evaluated only for
the current connect group. Otherwise, this rule is evaluated
for all groups to which the user is connected. (Note: for
checks performed by RACROUTE REQUEST=FASTAUTH with
the AUTHCHKS=CRITONLY option, only conditional access
list entries specifying WHEN(CRITERIA(SQLROLE…)) will
apply)
or, if i) did not grant access,
j) if a conditional access list td for ID(*) exists with requested
type of access, the user does not have the RESTRICTED
attribute set and the user satisfies the condition of the
conditional access list td. (Note: for checks performed by
RACROUTE REQUEST=FASTAUTH with the
AUTHCHKS=CRITONLY option, only conditional access list
entries specifying WHEN(CRITERIA(SQLROLE…)) will apply).
FDP_ACF.1.3 The TSF shall explicitly authorize access of subjects to objects based on
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the following additional rules:
a) the subject is a trusted subject and has specified a nested
ACEE in its call to RACF with a second user ID. In this case
access is allowed if either the primary user ID specified in
the first ACEE or the secondary user ID specified in the
nested ACEE has the requested access right to the object
and the object has been designated as eligible for nested
ACEE processing and the authorization check is made using
RACROUTE REQUEST=FASTAUTH.
b) when "program control" is activated (using the
WHEN(PROGRAM) option in the SETROPTS command) and
the program is protected by a profile in the PROGRAM class
and the user has at least EXECUTE access to this profile,
the user can execute the program in a clean z/OS
environment not "contaminated" by any untrusted
program. If the user has at least READ access then
untrusted programs may also be used by the user.
c) when "program control" is activated and "PADCHK" has
been defined in the profile for a program, a user may
access a data set via PADS if the program that attempts the
access or a higher program in the execution hierarchy is
allowed to access the file in the intended mode by the
conditional access list for the data set and all other active
programs not from the link pack area that have been
defined using the WHEN PROGRAM operand with “PADCHK”
are included in the conditional access list of the data set.
While a data set is open using PADS, for any new program
defined with PADCHK and started in this situation in the
same environment, the TOE checks that the new program is
also in the conditional access list of that data set.
Application note: The term “trusted” in this sense means “defined to
RACF via profiles in the PROGRAM class, or resident in the system link
pack area.
FDP_ACF.1.4 The TSF shall explicitly deny access of subjects to objects based on the
following additional rules: data sets that are not protected by a
discrete or generic profile can only be accessed by users with the
SPECIAL role.
7.1.3.4 Security attribute based access control: UNIX
(FDP_ACF.1(PSO-UNIX))
FDP_ACF.1.1 The TSF shall enforce the Persistent Storage Object Access Control Policy
to UNIX objects based on the following:
a) The z/OS UNIX user identity and group membership(s)
associated with a subject; and
b) The following access control attributes associated with an
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object: permission bits and (for file system objects) an
access control list capable of defining access rights read,
write, execute, or search. Default access rights are defined
by a system management attribute.
Access rights for file system objects are:
a) read
b) write
c) execute (ordinary files)
d) search (directories)
Access is defined by POSIX ACLs and permission bits. ACLs are
evaluated only when the FSSEC class is active in RACF.
Users who have the AUDITOR attribute have implicit SEARCH and
READ access for directories, without needing explicit permission
via the permission bits or ACLs.
FDP_ACF.1.2 The TSF shall enforce the following rules to determine if an operation
among controlled subjects and controlled objects is allowed:
The mandatory access control (Labeled Security Mode) must allow
access and the following algorithm for the discretionary access
control must also result in granting access.
If the FSACCESS class is active and SETROPTS RACLISTed, and if
the subject is accessing the root directory in a mounted zFS file
system (but not the system root directory), then if the MVS data
set name of the file system container is protected by a profile in
the FSACCESS class the subject must have UPDATE access to that
FSACCESS profile or the request will fail.
A subject must have search permission for every element of the
path name and the requested access for the object. A subject has
a specific type access to an object if:
a) the user has the AUDITOR attribute, the requested type of
access is READ or Search, and the object is a directory.
b) the effective user ID is 0 and the requested type of access
is not execute. If this is the case, access is granted. If the
effective user ID is 0, the requested type of access is
execute, there is no permission bit, and there is no ACL that
provides execute access to any user, access is denied.
c) the effective user ID is the one of the file owner and has
been granted access according to the owner permission
bits, access is granted.
d) the FSSEC class is active in RACF and an ACL exists within
the set of ACLs for the file that grants the required type of
access to the requesting user, access is granted.
e) the effective user ID is the one of the owner of the file, the
algorithm continues with step j.
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f) the effective group ID (GID) or any of the user’s
supplemental GIDs matches the group of the file and has
the requested type of access defined in the group
permission bits, access is granted.
g) the effective GID or any of the user’s supplemental GIDs
has an ACL defined for the file that allows the requested
type of access, access is granted.
h) the requested type of access is defined in the “other”
permission bits and the user does not have the RESTRICTED
attribute defined in his profile, access is granted.
i) the user has the RESTRICTED attribute defined and has the
requested type of access defined in the
RESTRICTED.FILESYS.ACCESS resource profile and the ACLs
associated with this profile, access is granted.
j) the user has the RESTRICTED attribute defined, the
RESTRICTED.FILESYS.ACCESS profile is not defined in RACF,
and the requested type of access is allowed according to
the “other” permission bits, access is granted.
k) the UNIXPRIV class is active and RACLISTed, and if the
SUPERUSER.FILESYS.ACLOVERRIDE resource is protected by
a profile in the UNIXPRIV class, then the user must have the
correct access level as documented for the ck_access
(IRRSKA00) callable service in z/OS Security Server: RACF
Callable Services. If the profile exists, it determines
whether file access is granted or denied.
l) this step of the algorithm is reached and no decision for
granting or denying access has been made, access is
denied.
FDP_ACF.1.3 The TSF shall explicitly authorize access of subjects to objects based on
the following additional rules:
a) the object is a z/OS UNIX file system object, the UNIXPRIV
class is active in RACF, the access was denied by an ACL
entry and the user has the requested type of access to the
file defined as access to the
SUPERUSER.FILESYS.ACLOVERRIDE profile
or
b) the object is a z/OS UNIX file system object, the UNIXPRIV
class is active in RACF, the access was denied by the
permission bits, the SUPERUSER.FILESYS.ACLOVERRIDE
profile is not defined in the UNIXPRIV class and the user
has the requested type of access to the
SUPERUSER.FILESYS profile, that is, if the user wants to
read the file, the user must have read access to the profile,
if the user wants to read and write the file, the user must
have write access to the profile, if the user wants to update
any directory, the user must have control access.
FDP_ACF.1.4 The TSF shall explicitly deny access of subjects to objects based on the
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following additional rules: none.
7.1.3.5 Security attribute based access control: LDAP
(FDP_ACF.1(PSO-LDAP))
FDP_ACF.1.1 The TSF shall enforce the Persistent Storage Object Access Control Policy
to LDAP objects based on the following:
a) The z/OS LDAP Bind DN identity associated with a subject,
together with the subject’s LDAP groups derived during
bind processing; and
b) LDAP ACLs or ACL Filters that determine whether the
access is allowed or not, and
c) The entryOwner attribute that applies to the object.
FDP_ACF.1.2 The TSF shall enforce the following rules to determine if an operation
among controlled subjects and controlled objects is allowed:
a) The owner of the LDAP object as well as the LDAP
administrator (identified by the administrator DN) are
always allowed full access to the object
b) In the case the z/OS LDAP user identity is neither the owner
nor the LDAP administrator access is determined by the
LDAP ACL associated with the LDAP object. This ACL is
determined as follows:
1. If the LDAP object has an explicit AclEntry, the ACLs
in this entry are used to determine access
2. If the LDAP object has no explicit AclEntry, the next
entry found when traversing up the directory tree
that has an explict AclEntry and has the AclPropagate
attribute set to TRUE, defines the AclEntry used to
determine access
3. If no LDAP object with an explicit AclEntry is found by
the above two steps, the default ACL is used to
determine access
c) ACLs in the AclEntry are evaluated as follows to determine
access:
1. if there is a specific value for the DN of the LDAP
user, the LDAP user gets those permissions only
2. else if there is a cn=this value and the DN of the
LDAP user is the distinguished name of the entry, the
LDAP user gets those permissions only
3. else if there are one or more group values that the
LDAP user is a member of, the LDAP user gets the
union of the permissions for those groups
4. else if there is a cn=authenticated value and the
LDAP user is authenticated to the directory with an
LDAP bind operation, the LDAP user gets those
permissions only
5. else if there is a cn=anybody value, the LDAP user
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gets those permissions only
6. otherwise the LDAP user gets no permissions
d) ACLs in the AclEntry may specify “grant” or “deny”
permissions for the object as a whole, for specific named
attributes within the object, or for attribute classes within
the object. The LDAP server will process the ACLs in a
precedence order to determine which ACL best applies to
the user’s request. The higher priority of the following list
have preference over lower priorities (listed from highest to
lowest):
1. attribute-level deny permissions
2. attribute-level grant permissions
3. access-class deny permissions
4. access-class grant permissions
After a user's base access has been determined, it may be
modified by Filter ACL entries. Filter ACLs can set permissions
based on any of the following:
a) bind DN
b) alternate DNs
c) pseudo DNs
d) groups that the bind or alternate DNs belong to
e) IP address of the client connection
f) time of day that directory entry was accessed
g) day of week that directory entry was accessed
h) the bind mechanism used
i) whether or not bind encryption was used
Filters support wildcards. Filters have the same syntax support as
LDAP search filters, where logical rules can be specified, such as
“&”(and), “|”(or), and “!”(not).
To allow flexibility, the aclEntry filtering mechanism also supports
three operation values that allow administrators to specify the
way in which filtered ACLs will take effect:
a) replace - the base effective ACL is replaced by the filtered
ACLs.
If administrators want a client from a given IP address to
only have a specific set of permissions, they would use
replace.
b) union - the base effective ACL is unioned with the filtered
ACLs, resulting in a new effective ACL. This would be used
to expand permissions.
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If administrators want a client from a given IP address to
have a specific set of permissions, at a minimum, they
would use union.
c) intersect - the base effective ACL is intersected with the
filtered ACLs. This would be used to reduce permissions.
If administrators want a client from a given IP address to
have a specific set of permissions, if and only if they
already have the permissions, they would use intersect.
As with the operator precedence described above, filter ACL
entries specifying “deny” take precedence over entries specifying
“grant”.
Application note: The owner of an LDAP object is determined by the
entryOwner attribute, or (if this does not exist for the LDAP object) by the
ownerSource attribute. The ownerSource attribute is not modifiable and is
managed by the TOE. It indicates the DN of the td that holds the
entryOwner attribute that applies to this object. This is the first td
encountered, while traveling up the directory tree from the object toward
the root, which has an entryOwner attribute and has the ownerPropagate
attribute set to TRUE.
FDP_ACF.1.3 The TSF shall explicitly authorize access of subjects to objects based on
the following additional rules: none.
FDP_ACF.1.4 The TSF shall explicitly deny access of subjects to objects based on the
following additional rules: none.
7.1.3.6 Security attribute based access control: UNIX IPC
(FDP_ACF.1(TSO))
FDP_ACF.1.1 The TSF shall enforce the Transient Storage Object Access Control Policy to
UNIX objects based on the following:
a) The z/OS UNIX user identity and group membership(s)
associated with a subject; and
b) The following access control attributes associated with an
object: permission bits. Default access rights are defined by
a system management attribute.
Access rights for z/OS UNIX IPC objects are:
a) read
b) write
Access is defined by permission bits only.
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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:
The mandatory access control (Labeled Security Mode) must allow
access and the following algorithm for the discretionary access
control must also result in granting access.
Access permissions are defined by permission bits of the IPC
object only. IPC objects don’t have ACLs associated with them.
The process creating the object defines the creator, owner, and
group based on the user ID of the current process. Access of a
process to an IPC object is allowed if access is allowed by the
mandatory access control (Labeled Security Mode) and the
following algorithm:
a) the effective UID of the current process is equal to the UID
of the IPC object creator or owner and the “owner”
permission bit for the requested type of access is set or,
b) the user is neither the owner nor the creator of the IPC
object and the effective UID of the current process is not
equal to the UID of the IPC object creator or owner and the
effective GID of the current process or any supplementary
z/OS UNIX GIDs the user is a member of is equal to the GID
of the IPC object and the “group” permission bit for the
requested type of access is set or,
c) the “other” permission bit for the requested type of access
is set for users who do not satisfy one of the first two
conditions.
FDP_ACF.1.3 The TSF shall explicitly authorize access of subjects to objects based on
the following additional rules: none.
FDP_ACF.1.4 The TSF shall explicitly deny access of subjects to objects based on the
following additional rules: none.
7.1.3.7 Export of user data without security attributes (FDP_ETC.1
(Labeled Security Mode only))
FDP_ETC.1.1 The TSF shall enforce the mandatory access control policy when
exporting unlabeled user data, controlled under the MAC policySFP(s),
outside of the TOE.
FDP_ETC.1.2 The TSF shall export the unlabeled user data without the user data's
associated security attributes
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7.1.3.8 Export of user data with security attributes (FDP_ETC.2(LS)
(Labeled Security Mode only))
FDP_ETC.2.1 The TSF shall enforce the mandatory access control policyMultilevel
Confidentiality Information Flow Control Policy when exporting labeled user
data, controlled under the MAC-policySFP(s), outside of the TOE.
FDP_ETC.2.2 The TSF shall export the labeled user data with the user data's associated
security attributes.
FDP_ETC.2.3 The TSF shall ensure that the security attributes, when exported outside
the TOE, are unambiguously associated with the exported labeled user
data.
FDP_ETC.2.4 The TSF shall enforce the following rules when labeled user data is
exported from the TOE:
a) When data is exported in hardcopy form, each page shall be
marked with a printed representation of the sensitivity label of the
subject requesting the export of the page. By default, this marking
shall appear on both the top and bottom of each printed page.
b) When the data is exported to a device the security attributes shall
be exported with the data using the printable label that is
assigned to the sensitivity label associated with the data by
the authorized administrator.
c) devices used to export data with security attributes shall
completely and unambiguously associate the security
attributes with the corresponding data.
Application note: A properly-authorized system administrator can export data with its
labels by placing all of the data to be exported in a multi-level zFS UNIX file system. The
z/OS data set that contains the zFS file system must be classified as SYSHIGH, which
ensures that only a system administrator who is authorized to work with this data can
directly read the z/OS data set containing the zFS UNIX file system.
The security labels of each file in the zFS file system are stored as extended attributes in
the file system and exported with the file system when the z/OS data set containing the
file system is written to a tape volume. When importing such a file system, it is the task of
the system administrator to ensure that the importing system is set up in a way that it
correctly interprets the labels.
It also possible to set up a zFS UNIX file system within a z/OS data set that has a
dedicated security label. The TOE then enforces that all zFS files within this file system
have the same security label as the z/OS data set containing the zFS file system. In this
case, any user who has read access to the z/OS data set may export the data set to a tape
volume in accordance with the security policy enforced by the TOE. When this tape
volume is read in another system, the labels of the files in the zFS file system (which are
all identical) can also be imported and interpreted.
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7.1.3.9 Complete information flow control: labeled security
(FDP_IFC.2(LS) (Labeled Security Mode only))
FDP_IFC.2.1 The TSF shall enforce the mandatory access control policy (MAC-policy)
Multilevel Confidentiality Information Flow Control Policy on
a) Subjects: jobs, started tasks, UNIX sessions, and TSO
sessions acting on behalf of users;
b) Objects: data sets, volumes, devices, z/OS UNIX file system
objects, z/OS UNIX IPC objects, terminals, TCP/IP
connections,
and all operations that cause that information to flow among them.
FDP_IFC.2.2 The TSF shall ensure that all operations that cause any information in the
TOE to flow among untrusted subjects and named objects in the TOE are
covered by the mandatory access control policyMultilevel Confidentiality
Information Flow Control Policy.
7.1.3.10 Complete information flow control: network
(FDP_IFC.2(NI))
FDP_IFC.2.1 The TSF shall enforce the Network Information Flow Control Policy on
a) Subjects:
i. unauthenticated external IT entities that send and receive
information mediated by the TOE;
ii. none that send and receive information mediated by the
TOE;
b) Information:
i. Network data routed through the TOE;
ii. no other information;
and all operations that cause that information to flow to and from subjects
covered by the SFP.
FDP_IFC.2.2 The TSF shall ensure that all operations that cause any information in the
TOE to flow to and from any subject in the TOE are covered by an
information flow control SFP.
Application note: This requirement covers IPv4 and IPv6 traffic.
7.1.3.11 Simple security attributes (FDP_IFF.1(NI))
FDP_IFF.1.1 The TSF shall enforce the Network Information Flow Control Policy based
on the following types of subject and information security attributes:
a) Object security attribute: the logical or physical network interface
through which the network data entered the TOE;
b) TCP/IP information security attributes:
i. Source and destination IP address,
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ii. Source and destination TCP port number,
iii. Source and destination UDP port number,
iv. Network protocol of IP, TCP, UDP, ICMP,
v. TCP header flags of SYN, ACK.
FDP_IFF.1.2 The TSF shall permit an information flow between a controlled subject and
controlled information via a controlled operation if the following rules hold:
For z/OS TCP/IP stacks configured for IP security, the TOE allows
an IP packet to be sent or to be received by a subject if a rule
described in FDP_IFF.1.3 applies and explicitly allows the packet
flow.
FDP_IFF.1.3 The TSF shall enforce the following rules:
Identification of IP packets using one or more of the following concepts:
a) Information security attribute matching;
b) Matching based on the state of a TCP connection;
Performing one or more of the following actions with identified network
data:
a) Discard the network data without any further processing;
b) Allow the network data to be processed unaltered by the TOE
according to the routing information maintained by the TOE;
c) Allow the network data to be processed after applying IPSec
protection according to local IPSec policy.
FDP_IFF.1.4 The TSF shall explicitly authorize an information flow based on the
following rules: no additional rules.
FDP_IFF.1.5 The TSF shall explicitly deny an information flow based on the following
rules: no additional rules.
Application note: This requirement covers IPv4 and IPv6 traffic.
7.1.3.12 Hierarchical security attributes (FDP_IFF.2(LS) (Labeled
Security Mode only))
FDP_IFF.2.1 The TSF shall enforce the mandatory access control policy Multilevel
Confidentiality Information Flow Control Policy based on the following
types of subject and object security attributes:
a) Subject security attributes:
i. Sensitivity label of the subject consisting of at least 8 site
definable hierarchical levels and a set of 60 site definable
non-hierarchical categories;
ii. none;
b) Object security attributes:
i. the sensitivity label of the object consisting of at least 8 site
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definable hierarchical levels and a set of 60 site definable
non-hierarchical categories;
ii. none.
FDP_IFF.2.2 The TSF shall permit an information flow between a controlled subject and
controlled object via a controlled operation if the following rules, based on
the ordering relationships between security attributes hold:
a) If the sensitivity label of the subject is greater than or equal to the
sensitivity label of the object, then the flow of information from the
object to the subject is permitted (a read operation);
b) If the sensitivity label of the object is greater than or equal to the
sensitivity label of the subject; then the flow of information from the
subject to the object is permitted (a write operation);
c) If the information flow is between objects, the sensitivity label of
the destination object must be greater than or equal to the
sensitivity label of the source object.
FDP_IFF.2.3 The TSF shall enforce the none.
FDP_IFF.2.4 The TSF shall explicitly authorize an information flow based on the
following rules: a user is permitted to bypass the information flow
policy, if the profile IRR.WRITEDOWN.BYUSER in the FACILITY class
exists and is active and the user has at least read access to it.
FDP_IFF.2.5 The TSF shall explicitly deny an information flow based on the following
rules: objects that are supposed to have a security label but do not
have a security label.
FDP_IFF.2.6 The TSF shall enforce the following relationships for any two valid
information flow control security attributes:
a) There exists an ordering function that, given two valid security
attributes, determines if the security attributes are equal, if one
security attribute is greater than the other, or if the security
attributes are incomparable with the following properties:
i. Sensitivity labels are equal if the hierarchical level of both
labels are equal and the non-hierarchical category sets are
identical;
ii. Sensitivity label A is greater than sensitivity label B if the
hierarchical level of A is greater than or equal to the
hierarchical level of B, and the non-hierarchical category set
of A is equal to or a superset of the non-hierarchical category
set of B;
iii. Sensitivity labels are incomparable if they are not equal and
neither label is greater than the other as defined in 1 and 2
above;
b) There exists a “least upper bound” in the set of security attributes,
such that, given any two valid security attributes, there is a valid
security attribute that is greater than or equal to the two valid
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security attributes; and
c) There exists a “greatest lower bound” in the set of security
attributes, such that, given any two valid security attributes, there
is a valid security attribute that is not greater than the two valid
security attributes.
7.1.3.13 Import of user data without security attributes
(FDP_ITC.1(LS) (Labeled Security Mode only))
FDP_ITC.1.1 The TSF shall enforce the mandatory access control policy Multilevel
Confidentiality Information Flow Control Policy when importing unlabeled
user data controlled under the mandatory access control policy SFP, from
outside of the TOE.
FDP_ITC.1.2 The TSF shall ignore any label-related security attributes associated with
the unlabeled user data when imported from outside the TOE.
FDP_ITC.1.3 The TSF shall enforce the following rules when importing unlabeled user
data controlled under the mandatory access control policy SFP from
outside the TOE:
a) When importing unlabeled data, the TSF shall allow the authorized
administrator to specify that the data is to be labeled with: a
label manually chosen by the authorized administrator.
Application note: See the Application note on FDP_ETC.1 for export of unlabeled data.
The requirement also applies for the import of RSA key pairs or Diffie-Hellman key pairs
imported to be used for the cryptographic operations of the TOE. The administrators need
to ensure using the MAC and DAC policy enforced by the TOE that this key material is
imported in a secure way and can not be imported by unauthorized users.
7.1.3.14 Import of user data with security attributes (FDP_ITC.2)
FDP_ITC.2.1 The TSF shall enforce the Persistent Storage Access Control Policy, Network
Information Flow Control Policy, none when importing user data, controlled
under the SFP, from outside of the TOE.
FDP_ITC.2.2 The TSF shall use the security attributes associated with the imported user
data.
FDP_ITC.2.3 The TSF shall ensure that the protocol used provides for the unambiguous
association between the security attributes and the user data received.
FDP_ITC.2.4 The TSF shall ensure that interpretation of the security attributes of the
imported user data is as intended by the source of the user data.
FDP_ITC.2.5 The TSF shall enforce the following rules when importing user data
controlled under the SFP from outside the TOE: none.
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Application note: If, for example, file names or file name extensions are used for access
control decisions, they are security attributes. In the case that an external file system is
mounted, this is considered an import of user data with security attributes, and therefore,
FDP_ITC rules must be defined and satisfied.
Application note: Based on the wording of FDP_ITC.2.1, the TOE complies with this SFR
even when it does not allow import of objects covered by the persistent or transient
storage object control policy.
However, network information flow control policy must always be covered by the TOE, as
it applies to the networking capability of the TOE to control traffic originating from outside
the TOE. In this case, the interpretation of security attributes is defined by the respective
protocol family.
7.1.3.15 Import of user data with security attributes: labeled
security (FDP_ITC.2(LS) (Labeled Security Mode only))
FDP_ITC.2.1 The TSF shall enforce the mandatory access control policy Multilevel
Confidentiality Information Flow Control Policy when importing labeled user
data, controlled under the mandatory access control policy SFP, from
outside of the TOE.
FDP_ITC.2.2 The TSF shall use the label-related security attributes associated with the
imported labeled user data.
FDP_ITC.2.3 The TSF shall ensure that the protocol used provides for the unambiguous
association between the security attributes and the labeled user data
received.
FDP_ITC.2.4 The TSF shall ensure that interpretation of the label-related security
attributes of the imported labeled user data is as intended by the source of
the user data.
FDP_ITC.2.5 The TSF shall enforce the following rules when importing labeled user data
controlled under the MAC policy SFP from outside the TOE:
a) devices used to import data with security attributes shall
unambiguously associate security labels with the
corresponding data.
Security labels consist of the following:
i. a hierarchical level; and
ii. a set of non-hierarchical categories.
7.1.3.16 Full residual information protection (FDP_RIP.2)
FDP_RIP.2.1 The TSF shall ensure that any previous information content of a resource is
made unavailable upon the allocation of the resource to all objects.
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7.1.3.17 Full residual information protection of resources
(FDP_RIP.3)
FDP_RIP.3.1 The TSF shall ensure that any previous information content of a resource is
made unavailable upon the allocation of the resource to all subjects or
users.
7.1.4 Identification and authentication (FIA)
7.1.4.1 Authentication failure handling (FIA_AFL.1)
FIA_AFL.1.1 The TSF shall detect when an administrator-configurable number of
consecutive unsuccessful authentication attempts for the authentication
methods passwords, password phrases and RACF PassTickets occur
related to all authentication events using these authentication
methods .
FIA_AFL.1.2 When the defined number of unsuccessful authentication attempts has been
surpassed, the TSF shall: set the user status to REVOKE.
7.1.4.2 User attribute definition: human users (FIA_ATD.1(HU))
FIA_ATD.1.1 The TSF shall maintain the following list of security attributes belonging to
individual human users:
a) User identifier;
b) Group memberships;
c) User password or password phrase;
d) Software token verification data;
e) Security roles;
f) default access rights for objects created by the user (UACC);
g) classes in which the user can define profiles (CLAUTH);
h) indicator that global access checking, the ID(*) entry on the
access list, and the UACC will not be used to allow this user
access to a protected resource (RESTRICTED);
i) z/OS UNIX UID (for users also defined to UNIX System
Services);
j) z/OS UNIX group memberships;
k) Kerberos principal name (for users defined to the z/OS
Network Authentication Service and for foreign Kerberos
principals that are defined to a Kerberos realm that has a
cross realm trust relationship with the z/OS Network
Authentication Service);
l) Kerberos ticket maximum lifespan for users defined to the
z/OS Network Authentication Service;
m) indicator of the encryption algorithm used by the z/OS
Network Authentication Service;
n) X.509v3 certificate(s).
Application note: The software token verification data can be implemented as transient
in nature. For example, a Kerberos ticket granting ticket or Kerberos ticket is created
when the user requests these tickets. The ticket granting server has the data to verify the
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Kerberos ticket granting ticket, whereas the application server has the data to verify the
Kerberos ticket.
Application note: Software token verification data for FIA_ATD.1(HU) is implemented by
the Kerberos principal name and X.509v3 certificates.
Application note: Attributes such as SPECIAL, GROUP-SPECIAL, AUDITOR, GROUP-
AUDITOR, and OPERATIONS designate roles in the model of this Security Target and are
therefore further explained in the role model in FMT_SMR.1
7.1.4.3 User attribute definition: technical users (FIA_ATD.1(TU))
FIA_ATD.1.1 The TSF shall maintain the following list of security attributes belonging to
individual technical users:
a) the logical or physical network interface through which the network
data entered the TOE;
b) identity of the logical or physical external interface through which
the user connected to the TOE;
c) Source IP address;
d) Destination IP address;
e) Destination port.
Application note: Bullet a) of this SFR relates to FDP_IFC.2(NI) and FDP_IFF.1(NI). In the
Common Criteria scheme, external entities are always considered to be users. Therefore,
every network data entity must be specified as user in this ST.
7.1.4.4 User attribute definition: EIA (FIA_ATD.1(EIA))
FIA_ATD.1.1 The TSF shall maintain the following list of security attributes belonging to
individual users for remote identification and authentication:
a) z/OS LDAP user (bind) identifier (for users also defined to
LDAP LDBM); and
b) z/OS LDAP group memberships (for users also defined to
LDAP LDBM).
7.1.4.5 User attribute definition: labeled security (FIA_ATD.1(LS)
(Labeled Security Mode only))
FIA_ATD.1.1 The TSF shall maintain the following list of security attributes belonging to
individual users:
a) Sensitivity label (in Labeled Security Mode),
b) user clearances (in Labeled Security Mode).
7.1.4.6 Verification of secrets (FIA_SOS.1)
FIA_SOS.1.1 The TSF shall provide a mechanism to verify that secrets meet the following
quality metric:
a) the probability that a secret can be obtained by an attacker during
the lifetime of the secret is less than 2^-20
Application note: Some authentication functions depend on cryptographic functions,
such as certificate-based client authentication. No strength of function analysis is
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provided in this ST for these, nor for any cryptographic key generation functions that may
be a part of the identification and authentication mechanisms.
7.1.4.7 Timing of authentication (FIA_UAU.1)
FIA_UAU.1.1 The TSF shall allow
a) the information flow covered by the Network Information Flow
Control Policy;
b) all functions allowed to be performed by the individual
pseudo-user assigned by the authorized administrator for
started procedures (started tasks);
c) administrator-specified anonymous access to specific data
via HTTP, FTP, or LDAP
on behalf of the user to be performed before the user is authenticated.
FIA_UAU.1.2 The TSF shall require each user to be successfully authenticated before
allowing any other TSF-mediated actions on behalf of that user.
Application note: In z/OS, predefined jobs known as started procedures (or started
tasks) may be started automatically, or by an operator who has the required privileges.
Those started tasks operate under a pseudo-user-ID assigned to them by the system
administrator when the started task job was created and stored in a protected data set.
z/OS allows the definition of protected user IDs for this purpose. Protected user IDs don’t
have a password or password phrase associated with them and cannot be used to log in
under TSO or UNIX. They need to be defined in RACF and they are bound by the same
RACF access control rules as a normal user. Activities performed by such a started task
are accounted to the pseudo-user-ID assigned to them and not with the ID of the operator
that started those tasks (because, in most cases, the operator would not know what those
started tasks are doing and the operator would not be allowed to access the resources
that the started tasks needs access to). No “user authentication” is performed for started
tasks. Instead, they can only be started from predefined libraries. Write access to those
libraries needs to be restricted to system administrators.
This concept does not allow an unauthenticated user to execute any program or
command on the TOE. Instead this concept allows an authenticated and properly
authorized user to start specific tasks that have previously been defined by an authorized
administrator and that operate under a pseudo–user-ID. The user that started this task
usually has no influence on what the task is doing. The fact that he started the Started
Procedure is auditable which ensures that the individual accountability for starting the
started procedure is given. The ID of the pseudo-user listed in the JOB statement of the
started procedure is not authenticated.
Also, z/OS allows an authorized administrator to configure the HTTP server, the FTP
server, or the LDAP server to allow “anonymous” access to selected data. Such access
occurs for HTTP or FTP using an administrator-specified user ID, which also is a form of
pseudo-user, and the administrator controls which data that user has access to, and
whether such anonymous access is enabled or not. For LDAP, the administrator can
control whether a particular LDAP LDBM server allows unauthenticated access or not, and
can further control which data in the LDBM database the unauthenticated user can
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access. For LDAP, the default is to allow anonymous access, and so the administrator who
chooses to enable LDAP access must usually disable the default anonymous access.
7.1.4.8 Multiple authentication mechanisms (FIA_UAU.5)
FIA_UAU.5.1 The TSF shall provide the following authentication mechanisms:
a) Authentication based on username and password and password
phrases;
b) Authentication based on software token verification data (digital
certificates, Kerberos tickets );
c) RACF PassTickets
to support user authentication.
FIA_UAU.5.2 The TSF shall authenticate any user's claimed identity according to the
following rules:
a) Authentication based on username and password, password phrase,
or RACF PassTicket is performed for TOE-originated requests and
credentials stored by the TSF;
b) Authentication based on software token verification data is
performed for TOE-originated requests;
c) TSF applications that perform user authentication accept any
of the above listed authentication mechanisms provided they
are configured for this mechanism (in the case of digital
certificates or Kerberos tickets) and the mechanism is also
supported for the user that attempts to authenticate.
Attempts to authenticate to such an application using a
mechanism the application is not configured for or where the
mechanism is not supported for the user will result in the
rejection of the authentication attempt.
Application note: For the term “software token verification data”, see the Application
note for FIA_ATD.1(HU).
7.1.4.9 Protected authentication feedback (FIA_UAU.7)
FIA_UAU.7.1 The TSF shall provide only obscured feedback to the user while the
authentication is in progress.
Application note: When entered during TSO LOGON the user has the option to use those
TSF functions in a way that prohibits passwords/phrases from being displayed. Passwords
for Operator LOGON are not displayed. Passwords a user enters via a JCL JOB statement
will be suppressed in any output of the JCL statements to prohibit the password from
being obtained by anybody reading the output.
For authentication performed by servers where the userid and password/phrase is
transferred over the network, the servers ensure that no feedback is provided as long as
the authentication is in progress. For protocols where the server can request the client to
suppress the display of characters entered by the user, such a request is sent before
passwords/phrases are requested to be entered by the user. This is done for telnet,
TN3270, and the r-commands. This still requires that the clients used implement those
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controls (e. g. switching to no-echo mode) correctly. In the case of FTP, SSH, Kerberos,
and LDAP the protocols do not have any control statements that can be sent to the client
to suppress the display of characters when a user enters a password/phrase. In those
cases the TSF have no control how the client obtains a user's password/phrase and just
ensures that no password/phrase related information is sent back to the client.
In all cases where clients operating as regular user programs are used it is outside of the
control of the TSF how those clients handle the password/phrase. Where those interfaces
are defined as part of the communication protocol, the TSF interfaces of the servers just
ensure that the clients get the required information to suppress displaying
passwords/phrases.
Client programs supplied by the TOE that operate as regular user programs (su, kinit,
kpasswd, ssh, etc.) do not echo the password/phrase, but as they are user programs they
are not part of the TSF.
Note that in the case of authentication via digital certificates, Kerberos tickets or
PassTickets, no feedback is provided during the time authentication is in progress.
7.1.4.10 Authentication policy decisions (FIA_UAU.8(EIA))
FIA_UAU.8.1 The TSF shall accept an authentication request holding the user credentials
from previously authenticated XMLAppliance instances that are
connected to NSS.
FIA_UAU.8.2 The TSF shall perform the authentication operation based on the
transmitted user credentials according to the rules for user
authentication enforced by RACF.
FIA_UAU.8.3 The TSF shall transmit the result of the authentication operation to the
XMLAppliance that submitted the authentication request according
to the following process: NSS calls RACF to perform the user
authentication and transmits the result returned by RACF to that
XMLAppliance.
7.1.4.11 Timing of identification (FIA_UID.1)
FIA_UID.1.1 The TSF shall allow access to the HTTP server, FTP server, or LDAP
server (restricted to the functions and resources accessible to the
pseudo user the administrator assigned for that purpose) on behalf
of the user to be performed before the user is identified.
FIA_UID.1.2 The TSF shall require each user to be successfully identified before allowing
any other TSF-mediated actions on behalf of that user.
Application note: The pseudo-user of a started task is identified within the JOB
statement of the JCL defining the started task. Users who start a started task (which will
not be executed with the ID of the user that started the task) need to be identified and
authenticated before they can perform this action. The FTP, LDAP, and HTTP server will
assign an administrator defined ID of a pseudo user to users that connect to those servers
without authenticating themselves. In this case all security related decisions are based on
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this ID.
7.1.4.12 Identification policy decisions (FIA_UID.3(EIA))
FIA_UID.3.1 The TSF shall accept an identification request holding the user credentials
from previously authenticated XMLAppliance instances that are
connected to NSS.
FIA_UID.3.2 The TSF shall perform the identification operation based on the transmitted
user credentials according to the rules for user identification enforced
by RACF.
FIA_UID.3.3 The TSF shall transmit the result of the identification operation to the
XMLAppliance that submitted the authentication request according
to the following process: NSS calls RACF to perform the user
authentication and transmits the result returned by RACF to that
XMLAppliance.
7.1.4.13 User-subject binding (FIA_USB.1(LS) (Labeled Security
Mode only))
FIA_USB.1.1 The TSF shall associate the following user security attributes with subjects
acting on the behalf of that user:
a) User sensitivity level that is used to enforce the mandatory access
control policy Multilevel Confidentiality Information Flow Control
Policy which consists of the following:
a. A hierarchical level; and
b. A set of non-hierarchical categories.
FIA_USB.1.2 The TSF shall enforce the following rules on the initial association of user
security attributes with subjects acting on the behalf of users:
a) The sensitivity label associated with a subject shall be
within the clearance range of the user.
FIA_USB.1.3 The TSF shall enforce the following rules governing changes to the user
security attributes associated with subjects acting on the behalf of users:
None.
7.1.4.14 Enhanced user-subject binding (FIA_USB.2)
FIA_USB.2.1 The TSF shall associate the following user security attributes with subjects
acting on the behalf of that user:
a) The RACF or LDAP user identity that is associated with auditable
events;
b) The RACF or LDAP or UNIX user security attributes that are used to
enforce the Persistent Storage Object Access Control Policy;
c) The RACF or LDAP or UNIX user security attributes that are used to
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enforce the Transient Storage Object Access Control Policy;
d) The software token that can be used for subsequent identification
and authentication with the TSF or other remote IT systems;
e) Active roles;
f) Active groups;
g) the RACF attributes/roles SPECIAL, group-SPECIAL, AUDITOR,
group-AUDITOR, CLAUTH, OPERATIONS, and group-
OPERATIONS.
FIA_USB.2.2 The TSF shall enforce the following rules on the initial association of user
security attributes with subjects acting on the behalf of users:
a) A started task executes with the user ID defined in the
started class or started procedures table defining the
started task.
b) A user that connects to the HTTP server or LDAP server
without authenticating will be bound to the identity the
installation has assigned for the unauthenticated user of the
server, and limited to accessing data that user is allowed to
access, unless and until the user is successfully identified
and authenticated using his own authentication information.
FIA_USB.2.3 The TSF shall enforce the following rules governing changes to the user
security attributes associated with subjects acting on the behalf of users:
a) A z/OS administrator may define specific z/OS applications to
execute with an administrator defined user ID.
b) A z/OS administrator may use the SURROGAT authority
mechanism to allow a user to switch his identify to another
defined user (e. g. submitting jobs or changing the ID with
the su command in the z/OS UNIX System Services
environment) without specifying the password/phrase for
this user.
In z/OS UNIX, the following additional rules apply:
a) The su command provides the ability to create a new session
with a new set of credentials (to be inherited by subjects
created within this session). The credentials are set to the
UID (RUID and EUID), GID (RGID and EGID), and
supplementary groups of the user requested. The user
issuing the su command must have the authority to use this
command, have the authority to switch to the specified UID
and either authenticates properly for this UID with the
password/phrase , has the SURROGAT authority for the new
UID or has BPX.SUPERUSER authority allowing him to switch
to UID 0 without supplying a password/phrase.
b) If the BPX.DAEMON profile exists in the FACILITY class of
RACF, a user with UID 0 needs to have authority other than
NONE to this profile to change his UID using the setuid or
seteuid system calls.
c) If the Ported Tools for z/OS Supplementary Toolkit Feature is
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installed, then if allowed by the configuration specified by
the security administrator in the sudoers file, a user can
utilize the sudo command to run specified UNIX commands,
with specified operands, under the authority of a different
user IDs.
Application note: In the z/OS BCP, a temporary change of the user ID is
not implemented. In z/OS UNIX System Services this is possible with a
slightly-modified semantic compared to other UNIX systems.
FIA_USB.2.4 The TSF shall enforce the following rules for the assignment of subject
security attributes not derived from user security attributes when a subject
is created:
a) When executing a program from a file with the set-user-ID-
on-execution bit (S_ISUID) set, the subject’s effective UID is
set to the owner ID of the file being executed; when
executing the program from a file with the set-group-ID-on-
execution bit (S_ISGID) set, the subject’s effective GID is set
to the group ID of the file being executed;
b) The Port of Entry (POE) is set to TERMINAL (when the user
has started his session from a terminal), CONSOLE (when
the user has started his session from z console), JESINPUT
(when the subject is started as a job entered via JES), or
SERVAUTH (when the user has started his session via a
network server application). Additional data is associated
with this security attribute depending on the input class (e.
g. the terminal ID in case of a terminal or the network zone
in case the Port of Entry type is SERVAUTH).
7.1.5 Security management (FMT)
7.1.5.1 Management of object security attributes: persistent
objects (FMT_MSA.1(PSO))
FMT_MSA.1.1
1. The TSF shall enforce the Persistent Storage Object Access Control
Policy to restrict the ability to modify [assignment: other
operations] the security attributes of the objects covered by the
SFP to the owner of the object and
a) For non-UNIX, non-LDAP objects:
1. users with the SPECIAL attribute or the appropriate
group-SPECIAL attribute and
2. users who have ALTER authority to the object
b) For UNIX objects a user with z/OS UNIX superuser privilege
c) For LDAP LDBM objects:
1. The directory Administrator
2. Members of the LDAP administrative group, subject
to the constraints defined in the administrative roles
to which they are assigned.
3. Users with DAC authority to move or rename an
object and
4. Users with write authority to restricted attributes in
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the object.
Application note: The required selection operation was performed by selecting the assignment
operation available. As no other actions are foreseen, a respective refinement operation deleting that
assignment was performed to demonstrate the absence of such operation.
7.1.5.2 Management of object security attributes: transient
objects (FMT_MSA.1(TSO))
FMT_MSA.1.1 The TSF shall enforce the Transient Storage Object Access Control Policy to
restrict the ability to modify [assignment: other operations] the security
attributes of the objects covered by the SFP to the owner of the object and
for z/OS UNIX IPC objects to a user with z/OS UNIX superuser
privilege.
Application note: The required selection operation was performed by selecting the assignment
operation available. As no other actions are foreseen, a respective refinement operation deleting that
assignment was performed to demonstrate the absence of such operation.
7.1.5.3 Management of object security attributes: labeled security
(FMT_MSA.1(LS) (Labeled Security Mode only))
FMT_MSA.1.1 The TSF shall enforce the mandatory access control policy Multilevel
Confidentiality Information Flow Control Policy to restrict the ability to
modify the label-related object security attributes to users with the
SPECIAL attribute.
7.1.5.4 Static attribute initialization: persistent objects
(FMT_MSA.3(PSO))
FMT_MSA.3.1 The TSF shall enforce the Persistent Storage Object Access Control Policy
to provide restrictive default values for security attributes that are used to
enforce the SFP.
FMT_MSA.3.2 The TSF shall allow the users with the SPECIAL attribute and the
owner of the profile protecting the object to specify alternative initial
values to override the default values when an object or information is
created.
7.1.5.5 Static attribute initialization: transient objects
(FMT_MSA.3(TSO))
FMT_MSA.3.1 The TSF shall enforce the Transient Storage Object Access Control Policy to
provide restrictive default values for security attributes that are used to
enforce the SFP.
FMT_MSA.3.2 The TSF shall allow the users with the SPECIAL attribute and the
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owner of the profile protecting the object to specify alternative initial
values to override the default values when an object or information is
created.
7.1.5.6 Static attribute initialization: network (FMT_MSA.3(NI))
FMT_MSA.3.1 The TSF shall enforce the Network Information Flow Control Policy to
provide restrictive default values for security attributes that are used to
enforce the SFP.
FMT_MSA.3.2 The TSF shall allow the users with READ access to the appropriate
profiles in the SERVAUTH class as specified in section
“Communications Server ipsec Command Interface” to specify
alternative initial values to override the default values when an object or
information is created.
Application note: The ability to perform IPSec, IP filtering, and defensive filtering related
network management functions can be delegated to users by providing them READ
access to the profile EZB.IPSECCMD.sysname.tcpprocname.CONTROL in the SERVAUTH
class of RACF. A list of profiles and the network management functions they protect can
be found in Network configuration and management.
7.1.5.7 Static attribute initialization: labeled security
(FMT_MSA.3(LS) (Labeled Security Mode only))
FMT_MSA.3.1 The TSF shall enforce the mandatory access control policy Multilevel
Confidentiality Information Flow Control Policy to provide restrictive default
values for security attributes that are used to enforce the SFP.
FMT_MSA.3.2 The TSF shall allow the users with the SPECIAL attribute and the
owner of the profile protecting the object to specify alternative initial
values to override the default values when an object or information is
created.
7.1.5.8 Security attribute value inheritance: persistent objects
(FMT_MSA.4(PSO))
FMT_MSA.4.1 The TSF shall use the following rules to set the value of security attributes
for Persistent Storage Objects:
MVS objects:
Object security attributes for MVS objects are stored in RACF
profiles. MVS objects inherit their object security attributes
from the RACF profile that most closely matches the object's
name.
LDAP LDBM objects:
LDAP LDBM objects can inherit their ACLs and owner
attributes from nodes above them in the directory hierarchy.
Inheritance is controlled by the aclPropagate and
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ownerPropagate attributes. An LDBM object's ACL and owner
attribute marked with these values inherit their respective
attribute to objects below in the hierarchy, unless another
ACL or owner attribute with the aclPropagate or
ownerPropagate value is encountered, or the ACL or owner
attributes for the object have been set explicitly.
7.1.5.9 Management of TSF data: audit events (FMT_MTD.1(AE))
FMT_MTD.1.1 The TSF shall restrict the ability to query, modify the set of audited events
to
a) users with the AUDITOR role
b) for events related to a profile: the profile owner.
Application note: This SFR applies to FAU_SEL.1.
7.1.5.10 Management of TSF data: audit storage (FMT_MTD.1(AS))
FMT_MTD.1.1 The TSF shall restrict the ability to clear, create, delete the audit
storage to users that satisfy the following rules:
a) users with the AUDITOR role
b) z/OS operators.
Application note: This SFR applies to FAU_STG.1.
Application note: The required selection was not performed since the term modify
already includes add and delete of parameters. To demonstrate the absence of that
selection, a respective refinement operation was performed.
7.1.5.11 Management of TSF data: audit trail threshold
(FMT_MTD.1(AT))
FMT_MTD.1.1 The TSF shall restrict the ability to modify, [selection: add, delete] the
a) threshold of the audit trail when an action is performed;
b) action when the threshold is reached
to the authorized administrator.
Application note: This SFR applies to FAU_STG.3.
7.1.5.12 Management of TSF data: audit storage failure
(FMT_MTD.1(AF))
FMT_MTD.1.1 The TSF shall restrict the ability to modify, [selection: add, delete] the
actions to be taken in case of audit storage failure to the authorized
administrator.
Application note: This SFR applies to FAU_STG.4.
Application note: The required selection was not performed since the term modify
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already includes add and delete of parameters. To demonstrate the absence of that
selection, a respective refinement operation was performed.
7.1.5.13 Management of TSF data: network filters (FMT_MTD.1(NI))
FMT_MTD.1.1 The TSF shall restrict the ability to query, modify, delete, perform
command-driven management functions for IPSec, IP filtering,
and defensive filtering configuration related to the security
attributes for the rules governing the
a) identification of network data;
b) actions performed on the identified network data
to users with READ access to the appropriate profiles in the
SERVAUTH class as specified in section "Communications Server
ipsec Command Interface".
Application note: This SFR applies to FDP_IFF.1(NI).
Application note: The ability to perform IPSec, IP filtering, and defensive filtering related
network management functions can be delegated to users by providing them READ access
to profiles of the form EZB.IPSECCMD.sysname.[one of: tcpname, clientname, sysname,
DMD, GLOBAL] (potentially followed by a function name) in the SERVAUTH class of RACF.
A list of profiles and the network management function they protect can be found in
section "Network configuration and management".
7.1.5.14 Management of TSF data: IPSec (FMT_MTD.1(NI2))
FMT_MTD.1.1 The TSF shall restrict the ability to perform management functions for
the IPSec network configuration to users with READ access to the
appropriate profiles in the SERVAUTH class as specified in section
Communications Server Network Management Interface.
Application note: The ability to perform IPSec related network management functions
can be delegated to users by providing them READ access to profiles of the form
EZB.NETMGMT.sysname.[one of: tcpname, clientname, sysname] (potentially followed by
a function name) in the SERVAUTH class of RACF. A list of profiles and the network
management function they protect can be found in section “Network configuration and
management”.
7.1.5.15 Management of TSF data: authentication threshold
(FMT_MTD.1(IAT))
FMT_MTD.1.1 The TSF shall restrict the ability to modify the threshold for unsuccessful
authentication attempts to users that satisfy the following rules:
a) user has SPECIAL
b) user has group-SPECIAL in the group that owns the user, or
group-SPECIAL in a higher group in the group tree if group
ownership is setup appropriately.
Application note: This SFR applies to FIA_AFL.1.
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7.1.5.16 Management of TSF data: account re-enablement
(FMT_MTD.1(IAF))
FMT_MTD.1.1 The TSF shall restrict the ability to re-enable the authentication to the
account subject to authentication failure to users that satisfy the
following rules:
a) user has SPECIAL
b) user has group-SPECIAL in the group that owns the user, or
group-SPECIAL in a higher group in the group tree if group
ownership is setup appropriately
In addition, the following users may change the REVOKE status
and the user's password or password phrase:
c) user has READ access to FACILITY resource
IRR.PASSWORD.RESET assuming the revoked user does not
have the SPECIAL, OPERATIONS, or AUDITOR attributes.
d) user has READ access to FACILITY resource
IRR.PWRESET.OWNER.owner-of-profile where "owner-of-
profile" specifies the user or group that owns the revoked
user, and the revoked user does not have the SPECIAL,
OPERATIONS, or AUDITOR attributes.
e) user has READ access to FACILITY resource
IRR.PWRESET.TREE.owner-of-tree where "owner-of-tree"
specifies a user or group that would have group-SPECIAL
over the revoked user, and the revoked user does not have
the SPECIAL, OPERATIONS, or AUDITOR attributes.
Application note: This SFR applies to FIA_AFL.1.
7.1.5.17 Management of TSF data: user security attributes
(FMT_MTD.1(IAU))
FMT_MTD.1.1 The TSF shall restrict the ability to initialize, modify, delete the user
security attributes other than authentication data, to users that satisfy
the following rules:
a) user has SPECIAL
b) users with CLAUTH attribute for the USER class
c) user has group-SPECIAL in the group that owns the user, or
group-SPECIAL in a higher group in the group tree if group
ownership is setup appropriately
d) LDAP administrators for administration of LDAP-based
users, groups, and roles.
Application note: This SFR applies to FIA_ATD.1, FIA_UAU.1, FIA_UID.1.
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7.1.5.18 Management of TSF data: authentication data
(FMT_MTD.1(IAU-AUTH))
FMT_MTD.1.1 The TSF shall restrict the ability to initialize, modify, delete the user
security attributes authentication data to users that satisfy the
following rules:
a) users authorized to modify their own authentication data
b) Users with the SPECIAL or appropriate group-SPECIAL
attribute can modify a user’s password/phrase;
c) Users with access to FACILITY resource
IRR.PASSWORD.RESET are allowed to reset
passwords/phrases for any user that does not have the
PROTECTED, SPECIAL, AUDITOR, or OPERATIONS attributes;
d) Users with access to FACILITY resource
IRR.PWRESET.OWNER.owner-value are allowed to reset
passwords/phrases for users owned by “owner-value” if
those users do not have the PROTECTED SPECIAL, AUDITOR,
or OPERATIONS attributes and are not exempted from reset
by the IRR.PWRESET.EXCLUDE.userID resource in the
FACILITY class;
e) Users with access to FACILITY resource
IRR.PWRESET.TREE.owner-value are allowed to reset
passwords/phrases for users in the scope of the group
specified by “owner-value” if those users do not have the
PROTECTED SPECIAL, AUDITOR, or OPERATIONS attributes
and are not exempted from reset by the
IRR.PWRESET.EXCLUDE.userID resource in the FACILITY
class. (Note: this “tree” function applies to the same target
users that group-SPECIAL would affect.);
f) Users may be allowed to renew or revoke their own digital
certificates via the z/OS PKI Services component.
Application note: This SFR applies to FIA_ATD.1, FIA_UAU.1, FIA_UID.1.
7.1.5.19 Management of TSF data: EIA (FMT_MTD.1(EIA))
FMT_MTD.1.1 The TSF shall restrict the ability to initialize, modify, delete the user
security attributes used for the remote identification and authentication
policy to the authorized administrator, or users that satisfy the
following rules:
a) user has SPECIAL
b) user has group-SPECIAL in the group that owns the user, or
group-SPECIAL in a higher group in the group tree if group
ownership is setup appropriately
In addition, the following users may reset the REVOKE status of a
revoked user account (re-enable the account) and the user's
password or password phrase:
c) user has READ access to FACILITY resource
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IRR.PASSWORD.RESET assuming the revoked user does not
have the SPECIAL, OPERATIONS, or AUDITOR attributes.
d) user has READ access to FACILITY resource
IRR.PWRESET.OWNER.owner-of-profile where "owner-of-
profile" specifies the user or group that owns the revoked
user, and the revoked user does not have the SPECIAL,
OPERATIONS, or AUDITOR attributes.
e) user has READ access to FACILITY resource
IRR.PWRESET.TREE.owner-of-tree where "owner-of-tree"
specifies a user or group that would have group-SPECIAL
over the revoked user, and the revoked user does not have
the SPECIAL, OPERATIONS, or AUDITOR attributes.
7.1.5.20 Management of TSF data: key import
(FMT_MTD.1(CRYPTO1))
FMT_MTD.1.1 The TSF shall restrict the ability to import or modify the cryptographic
keys to the authorized administrator.
Application note: The process of a user requesting a certificate from PKI Services
involves the user sending a public key to the PKI server. Similarly, authentication of a
client via SSL/TLS involves the client sending a public key to the server. For the purposes
of this ST, neither of those operations, nor other operations similar to them, are
considered to be importation of a cryptographic key.
7.1.5.21 Management of TSF data: digital certificates
(FMT_MTD.1(CRYPTO2))
FMT_MTD.1.1 The TSF shall restrict the ability to perform management functions for
the digital certificates to users with the SPECIAL attribute and
users assigned authority to specific management functions as
defined in the tables in the section on managing digital
certificates.
Application note: To perform a specific management function for digital certificates, a
user that does not have the SPECIAL attribute must have RACF authority to a profile of the
type IRR.DIGTCERT.function in the FACILITY class where function is the name of the
management function. The list of management functions and the semantics of READ,
UPDATE and CONTROL authority for each function is defined in the tables in Authority
checking for RACDCERT Processing, Authority Checking for R_datalib Processing and
Authority Checking for PKCS#11 Cryptographic Tokens in the ICSF TKDS. That chapter
also discusses use of resources in the CRYPTOZ resource class to control access to
PKCS#11 tokens. To determine the authority a user has to those profiles, RACF uses the
algorithm defined in FDP_ACF.1(1).
7.1.5.22 Management of TSF data: additional configuration
(FMT_MTD.1(ADD))
FMT_MTD.1.1 The TSF shall restrict the ability to initialize or change the additional
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TOE configuration parameters to authorized administrators.
Application note: This includes configuration information such as network configuration
associated with the TCP/IP stack, as well as LDAP server configuration, FTP server
configuration, HTTP server configuration, PKI Services configuration and management,
basic system configuration information, etc.
7.1.5.23 Revocation: objects (FMT_REV.1(OBJ))
FMT_REV.1.1 The TSF shall restrict the ability to revoke object security attributes defined
by SFPs associated with the corresponding object under the control of the
TSF to users that satisfy the following rules:
a) users authorized to modify the security attributes covered
by the Persistent Storage Object Access Control Policy or
the Transient Storage Object Access Control Policy, or (in
Labeled Security Mode) the mandatory access control policy.
FMT_REV.1.2 The TSF shall enforce the following rules:
a) The access rights associated with an object shall be enforced when
an access check is made;
b) Labeled Security Mode only: the rules of the mandatory
access control policy are enforced on all future operations.
Application note: For the access rights to data sets, z/OS UNIX file system objects,
volumes, terminals, and TCP/IP connections, the access checks are performed once when
the user starts to use the resource and are not checked again until the user releases the
resource and attempts to use it again. Immediate revocation for these attributes can be
achieved by terminating all active jobs of the user, his TSO sessions and all the z/OS UNIX
processes acting on behalf of this user.
7.1.5.24 Revocation: users (FMT_REV.1(USR))
FMT_REV.1.1 The TSF shall restrict the ability to revoke user security attributes defined
by the SFP associated with the corresponding user under the control of the
TSF to the authorized roles as defined by FMT_SMR.1 bullets a), d),
e), f), l), n), o), r), and s).
Application note: z/OS has several kinds of authorized administrators,
including users with SPECIAL and group-SPECIAL attributes, as well as
owners and users with authority to change another user’s
password/phrase. All of these can, in some sense, revoke some or all of a
user’s security attributes. Additionally, via PKI Services, users who own a
digital certificate may request revocation of their certificate, and posting of
that certificate to the certificate revocation list (CRL) maintained by PKI
Services.
FMT_REV.1.2 The TSF shall enforce the following rules:
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a) The enforcement of the revocation of security-relevant
authorizations with the next user-subject binding process during the
next authentication of the user;
b) the immediate revocation of security-relevant authorization.
7.1.5.25 Specification of Management Functions (FMT_SMF.1)
FMT_SMF.1.1 The TSF shall be capable of performing the following management
functions:
a) Management of auditing;
b) Management of cryptographic network protocols;
c) Management of Persistent Storage Object Access Control Policy;
d) Management of Transient Storage Object Access Control Policy;
e) Management of Network Information Flow Control Policy;
f) Management of identification and authentication policy;
g) Management of user security attributes;
h) Management of cryptographic keys;
i) Management of digital certificates;
j) Management of other TOE configuration data.
7.1.5.26 Security roles (FMT_SMR.1)
FMT_SMR.1.1 The TSF shall maintain the roles:
a) User role with the following rights:
i. Users are authorized to modify their own user password;
ii. Users are authorized to modify the access control
permissions for the named objects they own;
b) users authorized by the discretionary access control
policy to modify object security attributes;
c) in Labeled Security Mode: users authorized by the
mandatory access control policy to modify object security
attributes;
d) users authorized to modify their own authentication data;
e) users authorized to perform administrative actions within
a defined group (group-SPECIAL attribute)
f) users authorized to perform administrative actions for
user or group security attributes via ownership
g) RACF auditors (users who have the RACF AUDITOR
attribute in their profiles)
h) RACF group auditors (users who have the RACF group-
AUDITOR attribute in their profiles)
i) Operations roles (users with the OPERATIONS attribute)
j) z/OS operators (users who are allowed to issue operator
commands)
k) z/OS pseudo-user (protected user IDs used for executing
defined started tasks, and for “anonymous” access to
administrator-specified data via HTTP or LDAP)
l) z/OS UNIX superuser
m) LDAP Administrator (as specified in the LDAP
configuration file)
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n) Additional LDAP administration roles if the LDAP
configuration file specifies that the LDAP administration
group is enabled: Directory Data Administrator, No
Administrator, Replication Administrator, Root
Administrator, Schema Administrator, Server
Configuration Group Member, Password Administrator,
and Operational Administrator.
o) PKI Services Administrator (as specified by authorization
to FACILITY resource IRR.RPKISERV.PKIADMIN and for
some functions specific IRR.DIGTCERT.function-name
resources.)
p) Users authorized to perform management operations for
digital certificates based on access rights to RACF profiles
protecting the individual management operations
q) Users authorized to perform IPSec network management
functions based on access rights to RACF profiles
protecting the individual management operations
r) Users authorized to perform other management functions
based on access rights to RACF profiles protecting the
individual management operations
s) authorized administrator (user with the SPECIAL
attribute).
FMT_SMR.1.2 The TSF shall be able to associate users with roles.
7.1.6 Protection of the TSF (FPT)
7.1.6.1 Reliable time stamps (FPT_STM.1)
FPT_STM.1.1 The TSF shall be able to provide reliable time stamps.
7.1.6.2 Inter-TSF basic TSF data consistency (FPT_TDC.1)
FPT_TDC.1.1 The TSF shall provide the capability to consistently interpret information
in the RACF database and extended attributes of UNIX file
system objects when shared between the TSF and another trusted IT
product.
FPT_TDC.1.2 The TSF shall use the rules to interpret RACF profiles and
authorizations and the rules to interpret extended attributes of
UNIX file system objects when interpreting the TSF data from another
trusted IT product.
Application note: Inter-TSF data consistency shall ensure that access control
information is consistently interpreted when this information is shared between different
instantiations of the TOE or when UNIX file system objects with their extended attributes
are exported from one system and imported into another system. The discretionary
access control information either has to be identical (which requires that the same users,
groups and user membership of groups are defined in the involved systems) or this
information has to be updated accordingly by a system administrator before the UNIX file
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system object is made available to other user on the system importing the object.
7.1.6.3 Inter-TSF basic TSF data consistency: labeled security
(FPT_TDC.1(LS) (Labeled Security Mode only))
FPT_TDC.1.1 The TSF shall provide the capability to consistently interpret label-related
security attributes, no other TSF data when shared between the TSF and
another trusted IT product.
FPT_TDC.1.2 The TSF shall use the list of security labels to be applied by the TSF
when interpreting the TSF data from another trusted IT product.
Application note: Inter-TSF data consistency shall ensure that access control
information including security labels are consistently interpreted when this information is
shared between different instantiations of the TOE. In order to do this, at least the
definition of the security labels between the systems involved have to be identical.
7.1.7 TOE access (FTA)
7.1.7.1 TSF-initiated session locking (FTA_SSL.1)
FTA_SSL.1.1 The TSF shall lock an interactive session to a human user maintained by the
TSF after an administrator-defined time interval of user inactivity by:
a) clearing or overwriting TSF controlled display devices, making the
current contents unreadable;
b) disabling any activity of the user's TSF controlled data access/TSF
controlled display devices other than unlocking the session.
FTA_SSL.1.2 The TSF shall require the following events to occur prior to unlocking the
session:
a) Successful re-authentication with the credentials of the user owning
the session using one of the authentication methods out of the
list of allowed methods specified in FIA_UAU.5;
b) no other events.
Application note: This SFR applies to directly attached terminals, not networked
sessions.
Application note: It is possible that the TSF establishes a connection to a session on a
remote trusted IT system, for example when using SSH. This remote trusted IT system
maintains the session established with the communication channel. The locking
requirement however applies to the session maintained by the TSF only as the TSF can
only exercise control of the sessions it maintains.
7.1.7.2 User-initiated locking (FTA_SSL.2)
FTA_SSL.2.1 The TSF shall allow user-initiated locking of the user's own interactive
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session maintained by the TSF, by:
a) clearing or overwriting TSF controlled display devices, making the
current contents unreadable;
b) disabling any activity of the user's TSF controlled data access/TSF
controlled display devices other than unlocking the session.
FTA_SSL.2.2 The TSF shall require the following events to occur prior to unlocking the
session:
a) Successful re-authentication with the credentials of the user owning
the session using one of the authentication methods from the
list of allowed methods specified in FIA_UAU.5;
b) no other events.
Application note: This SFR applies to directly attached terminals, not networked
sessions.
Application note: See also application note for FTA_SSL.1
7.1.8 Trusted path/channels (FTP)
7.1.8.1 Inter-TSF trusted channel (FTP_ITC.1)
FTP_ITC.1.1 The TSF shall provide a communication channel between itself and another
trusted IT product that is logically distinct from other communication
channels and provides assured identification of its end points and protection
of the channel data from modification and disclosure using the following
mechanisms:
a) Cryptographically-protected communication channel using SSLv3,
TLSv1, TLSv1.1, SSHv2, GSSAPI with message privacy
functions using the Kerberos v5 mechanism, or IPSec
protocols offered by TOE services;
b) physically protected communication channels provided by
the TOE environment.
FTP_ITC.1.2 The TSF shall permit the TSF, another trusted IT product to initiate
communication via the trusted channel.
FTP_ITC.1.3 The TSF shall initiate communication via the trusted channel for all security
functions specified in the ST that interact with remote trusted IT systems
and no other functions and conditions.
7.2 Security Functional Requirements Rationale
7.2.1 Security Requirements Coverage
The following table provides a mapping of SFR to the security objectives, showing that each
security functional requirement addresses at least one security objective.
Security Functional Requirements Objectives
FAU_GEN.1 O.AUDITING
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Security Functional Requirements Objectives
FAU_GEN.2 O.AUDITING
FAU_SAR.1 O.AUDITING
FAU_SAR.2 O.AUDITING
FAU_SAR.3 O.AUDITING
FAU_SEL.1 O.AUDITING
FAU_STG.1 O.AUDITING
FAU_STG.3 O.AUDITING
FAU_STG.4 O.AUDITING
FCS_CKM.1(SYM) O.CRYPTO.NET, O.CRYPTO.BASIC
FCS_CKM.1(RSA) O.CRYPTO.NET, O.CRYPTO.BASIC
FCS_CKM.1(DSA) O.CRYPTO.NET, O.CRYPTO.BASIC
FCS_CKM_EXT.1(ECDSA) O.CRYPTO.BASIC
FCS_CKM.2(NET) O.CRYPTO.NET
FCS_CKM.4 O.CRYPTO.NET, O.CRYPTO.BASIC
FCS_COP_EXT.1(SGN) O.CRYPTO.BASIC
FCS_COP.1(NET) O.CRYPTO.NET
FCS_COP_EXT.1(CRYPTO-ENC) O.CRYPTO.BASIC
FCS_COP_EXT.1(CRYPTO-MD) O.CRYPTO.BASIC
FCS_COP_EXT.1(CRYPTO-SGN) O.CRYPTO.BASIC
FCS_RNG.1 O.CRYPTO.NET
FDP_ACC.1(PSO) O.DISCRETIONARY.ACCESS
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Security Functional Requirements Objectives
FDP_ACC.1(TSO) O.SUBJECT.COM
FDP_ACF.1(PSO-MVS) O.DISCRETIONARY.ACCESS
FDP_ACF.1(PSO-UNIX) O.DISCRETIONARY.ACCESS
FDP_ACF.1(PSO-LDAP) O.DISCRETIONARY.ACCESS
FDP_ACF.1(TSO) O.SUBJECT.COM
FDP_ETC.1 (Labeled Security Mode only) O.LS.CONFIDENTIALITY
FDP_ETC.2(LS) (Labeled Security Mode only) O.LS.CONFIDENTIALITY,
O.LS.PRINT
FDP_IFC.2(LS) (Labeled Security Mode only) O.LS.CONFIDENTIALITY
FDP_IFC.2(NI) O.NETWORK.FLOW
FDP_IFF.1(NI) O.NETWORK.FLOW
FDP_IFF.2(LS) (Labeled Security Mode only) O.LS.CONFIDENTIALITY
FDP_ITC.1(LS) (Labeled Security Mode only) O.LS.CONFIDENTIALITY,
O.LS.LABEL
FDP_ITC.2 O.DISCRETIONARY.ACCESS,
O.NETWORK-FLOW,
O.SUBJECT.COM
FDP_ITC.2(LS) (Labeled Security Mode only) O.LS.CONFIDENTIALITY,
O.LS.LABEL
FDP_RIP.2 O.AUDITING,
O.CRYPTO.NET,
O.DISCRETIONARY.ACCESS,
O.I&A,
O.NETWORK.FLOW,
O.SUBJECT.COM
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FDP_RIP.3 O.AUDITING,
O.CRYPTO.NET,
O.DISCRETIONARY.ACCESS,
O.I&A,
O.NETWORK.FLOW,
O.SUBJECT.COM
FIA_AFL.1 O.I&A
FIA_ATD.1(HU) O.I&A
FIA_ATD.1(TU) O.NETWORK.FLOW
FIA_ATD.1(EIA) O.I&A.REMOTE
FIA_ATD.1(LS) (Labeled Security Mode only) O.LS.LABEL
FIA_SOS.1 O.I&A
FIA_UAU.1 O.I&A
FIA_UAU.5 O.I&A,
O.I&A.MULTIPLE
FIA_UAU.7 O.I&A
FIA_UAU.8(EIA) O.I&A.REMOTE
FIA_UID.1 O.I&A,
O.NETWORK.FLOW
FIA_UID.3(EIA) O.I&A.REMOTE
FIA_USB.1(LS) (Labeled Security Mode only) O.LS.LABEL
FIA_USB.2 O.I&A
FMT_MSA.1(PSO) O.MANAGE
FMT_MSA.1(TSO) O.MANAGE
FMT_MSA.1(LS) (Labeled Security Mode only) O.LS.LABEL
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FMT_MSA.3(PSO) O.MANAGE
FMT_MSA.3(TSO) O.MANAGE
FMT_MSA.3(NI) O.MANAGE
FMT_MSA.3(LS) (Labeled Security Mode only) O.LS.LABEL
FMT_MSA.4(PSO) O.MANAGE
FMT_MTD.1(AE) O.MANAGE
FMT_MTD.1(AS) O.MANAGE
FMT_MTD.1(AT) O.MANAGE
FMT_MTD.1(AF) O.MANAGE
FMT_MTD.1(NI) O.MANAGE
FMT_MTD.1(NI2) O.MANAGE
FMT_MTD.1(IAT) O.MANAGE
FMT_MTD.1(IAF) O.MANAGE
FMT_MTD.1(IAU) O.MANAGE
FMT_MTD.1(IAU-AUTH) O.MANAGE
FMT_MTD.1(EIA) O.I&A.REMOTE
FMT_MTD.1(CRYPTO1) O.MANAGE
FMT_MTD.1(CRYPTO2) O.MANAGE
FMT_MTD.1(ADD) O.MANAGE
FMT_REV.1(OBJ) O.MANAGE
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FMT_REV.1(USR) O.MANAGE
FMT_SMF.1 O.MANAGE
FMT_SMR.1 O.MANAGE
FPT_STM.1 O.AUDITING
FPT_TDC.1 O.DISCRETIONARY.ACCESS,
O.NETWORK.FLOW,
O.SUBJECT.COM
FPT_TDC.1(LS) (Labeled Security Mode only) O.LS.CONFIDENTIALITY,
O.LS.LABEL
FTA_SSL.1 O.I&A
FTA_SSL.2 O.I&A
FTP_ITC.1 O.TRUSTED_CHANNEL
Table 8: Mapping of security functional requirements to security objectives
7.2.2 Security Requirements Sufficiency
The following rationale provides justification for each security objective for the TOE, showing
that the security functional requirements are suitable to meet and achieve the security
objectives:
Security objectives Rationale
O.AUDITING The events to be audited are defined in FAU_GEN.1 and
are associated with the identity of the user that caused
the event (FAU_GEN.2). Authorized users are provided the
capability to read the audit records (FAU_SAR.1), while all
other users are denied access to the audit records
(FAU_SAR.2). Audit trails can be searched for events
belonging to users, objects, or labels(FAU_SAR.3). The
authorized user must have the capability to specify which
audit records are generated (FAU_SEL.1). The TOE
prevents the audit log from being modified or deleted
(FAU_STG.1) and ensures that the audit log is not lost due
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to resource shortage (FAU_STG.3, FAU_STG.4). To support
auditing, the TOE is able to maintain proper time stamps
(FPT_STM.1).
The protection of reused resources ensures that no data
leaks from other protected sources (FDP_RIP.2, FDP_RIP.3).
O.CRYPTO.NET The cryptographically-protected network protocol
(FCS_COP.1_NET) is supported by the generation of
symmetric keys (FCS_CKM.1_SYM), as well as asymmetric
keys (FCS_CKM.1_RSA, FCS_CKM.1_DSA). Key generation
is supported by the provision of good-quality random
numbers (FCS_RNG.1). As part of the cryptographic
network protocol, the TOE securely exchanges the
symmetric key with a remote trusted IT system
(FCS_CKM.2_NET). The TOE ensures that all keys are
zeroized upon de-allocation (FCS_CKM.4).
The protection of reused resources ensures that no data
leaks from other protected sources (FDP_RIP.2, FDP_RIP.3).
O.CRYPTO.BASIC Basic cryptographic services are provided for symmetric
key generation (FCS_CKM.1(SYM)), for RSA key pair
generation (FCS_CKM.1(RSA)), for DSA key pair generation
(FCS_CKM.1(DSA)), for ECDSA key pair generation
(FCS_CKM_EXT.1(ECDSA)), for signature generation and
verification (FCS_COP_EXT.1(SGN) and
FCS_COP_EXT.1(CRYPTO-SGN)), for general encryption and
decryption services (FCS_COP_EXT.1(CRYPTO-ENC)), and
for message digest generation (FCS_COP_EXT.1(CRYPTO-
MD).
O.DISCRETIONARY.ACCESS The TSF must control access to resources based on the
identity of users that are allowed to specify which
resources they want to access for storing their data.
The access control policy must have a defined scope of
control (FDP_ACC.1_PSO). The rules for the access control
policy are defined (FDP_ACF.1_PSO-MVS, FDP_ACF.1_PSO-
UNIX, FDP_ACF.1_PSO-LDAP). When import of user data is
allowed, the TOE must ensure that user data security
attributes required by the access control policy are
correctly interpreted (FDP_ITC.2, FPT_TDC.1).
The protection of reused resources ensures that no data
leaks from other protected sources (FDP_RIP.2, FDP_RIP.3).
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Security objectives Rationale
O.NETWORK.FLOW The packet filter mechanism controls the information
flowing between different entities (FDP_IFC.2_NI). The TOE
implements a rule-set governing the information flow
(FDP_IFF.1_NI). To facilitate the information flow control,
the information must be identified (FIA_UID.1) based on
security attributes the TOE can maintain (FIA_ATD.1_TU).
The TOE must ensure that security attributes of the
network data required by the information flow control
policy are correctly interpreted (FDP_ITC.2, FPT_TDC.1).
The protection of reused resources ensures that no data
leaks from other protected sources (FDP_RIP.2, FDP_RIP.3).
O.SUBJECT.COM The TSF must control the exchange of data using transient
storage objects between subjects based on the identity of
users.
The access control policy must have a defined scope of
control (FDP_ACC.1_TSO). The rules for the access control
policy are defined (FDP_ACF.1_TSO). When import of user
data is allowed, the TOE must ensure that user data
security attributes required by the access control policy
are correctly interpreted (FDP_ITC.2, FPT_TDC.1).
The protection of reused resources ensures that no data
leaks from other protected sources (FDP_RIP.2, FDP_RIP.3).
O.I&A The TSF must ensure that only authorized users gain
access to the TOE and its resources. Users authorized to
access the TOE must use an identification and
authentication process (FIA_UID.1, FIA_UAU.1). Multiple
I&A mechanisms are allowed as specified in FIA_UAU.5. To
ensure authorized access to the TOE, authentication data
is protected (FIA_ATD.1_HU, FIA_UAU.7). Proper
authorization for subjects acting on behalf of users is also
ensured (FIA_USB.2). The appropriate strength of the
authentication mechanism is ensured (FIA_SOS.1). To
support the strength of authentication methods, the TOE
is capable of identifying and reacting to unsuccessful
authentication attempts (FIA_AFL.1). In addition, user-
initiated and TSF-initiated session locking (FTA_SSL.1,
FTA_SSL.2) protect the authenticated user's session.
The protection of reused resources ensures that no data
leaks from other protected sources (FDP_RIP.2, FDP_RIP.3).
O.MANAGE The TOE provides management interfaces globally defined
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Security objectives Rationale
in FMT_SMF.1 for:
• the access control policies (FMT_MSA.1_PSO,
FMT_MSA.1_TSO, FMT_MSA.3_PSO,
FMT_MSA.3_TSO);
• the information flow control policy (FMT_MSA.3_NI,
FMT_MTD.1_NI, FMT_MTD.1_NI2);
• the auditing aspects (FMT_MTD.1_AE,
FMT_MTD.1_AS, FMT_MTD.1_AT, FMT_MTD.1_AF);
• the identification and authentication aspects
(FMT_MTD.1_IAT, FMT_MTD.1_IAF, FMT_MTD.1_IAU,
FMT_MTD.1_IAU-AUTH);
• the management of cryptographic functions,
especially for cryptographic keys
(FMT_MTD.1_CRYPTO1) and digital certificates
(FMT_MTD.1_CRYPTO2);
• the configuration of networks and network services
(FMT_MTD.1_ADD).
Persistently stored user data is stored either in
hierarchical or relational fashion, which implies an
inheritance of security attributes from parent objects
(FMT_MSA.4_PSO).
The rights management for the different management
aspects is defined with FMT_SMR.1.
The management interfaces for the revocation of user and
object attributes is provided with (FMT_REV.1_OBJ,
FMT_REV.1_USR).
O.TRUSTED_CHANNEL The TOE provides a trusted channel protecting
communication between a remote trusted IT system and
itself (FTP_ITC.1).
O.I&A.REMOTE The remotely triggerable I&A policy is defined by the
identification mechanism (FIA_UID.3_EIA), the
authentication mechanism (FIA_UAU.8_EIA) and the
specification of the security attributes applicable to this
policy (FIA_ATD.1_EIA). The management aspect of this
I&A policy is covered by FMT_MTD.1_EIA.
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O.I&A.MULTIPLE The TOE shall provide multiple I&A policies, at least one
for local and one for remote I&A which is specified with
FIA_UAU.5.
O.LS.CONFIDENTIALITY The information flow control policy is defined by specifying
the subjects, objects, security attributes and rules in
FDP_IFC.2_LS and FDP_IFF.2_LS. Supportive to the
enforcement of the policy are the automated label
assignment when exporting data (FDP_ETC.1,
FDP_ETC.2_LS) and during the import of data
(FDP_ITC.1_LS, FDP_ITC.2_LS). For assigning labels to
imported data, the label information transmitted with the
data must be interpretable by the TOE (FPT_TDC.1_LS).
O.LS.PRINT The addition of label information on exported data during
printing is directly addressed by FDP_ETC.2_LS.
O.LS.LABEL The assignment of labels to users is performed during
user-subject binding (FIA_USB.1_LS) with security
attributes maintained by the TOE (FIA_ATD.1_LS). Object
labels are assigned to objects when importing them into
the TOE (FDP_ITC.1_LS, FDP_ITC.2_LS, FPT_TDC.1_LS). The
management of labels is allowed for the TOE with
(FMT_MSA.1_LS, FMT_MSA.3_LS).
Table 9: Security objectives for the TOE rationale
7.2.3 Security Requirements Dependency Analysis
The following table demonstrates the dependencies of SFRs modeled in CC Part 2 and how
the SFRs for the TOE resolve those dependencies:
Security Functional
Requirement
Dependencies Resolution
FAU_GEN.1 FPT_STM.1 FPT_STM.1
FAU_GEN.2 FAU_GEN.1 FAU_GEN.1
FIA_UID.1 FIA_UID.1
FAU_SAR.1 FAU_GEN.1 FAU_GEN.1
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Dependencies Resolution
FAU_SAR.2 FAU_SAR.1 FAU_SAR.1
FAU_SAR.3 FAU_SAR.1 FAU_SAR.1
FAU_SEL.1 FAU_GEN.1 FAU_GEN.1
FMT_MTD.1 FMT_MTD.1(AE)
FAU_STG.1 FAU_GEN.1 FAU_GEN.1
FAU_STG.3 FAU_STG.1 FAU_STG.1
FAU_STG.4 FAU_STG.1 FAU_STG.1
FCS_CKM.1(SYM) FCS_COP.1 FCS_COP.1(NET)
FCS_CKM.4 FCS_CKM.4
FCS_CKM.1(RSA) FCS_COP.1 FCS_COP.1(NET)
FCS_CKM.4 FCS_CKM.4
FCS_CKM.1(DSA) FCS_COP.1 FCS_COP.1(NET)
FCS_CKM.4 FCS_CKM.4
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Security Functional
Requirement
Dependencies Resolution
FCS_CKM_EXT.1(ECDS
A)
FCS_COP.1 FCS_COP_EXT.1(CRYPTO-SGN)
FCS_CKM.4 FCS_CKM.4
FCS_CKM.2(NET) FCS_CKM.1 FCS_CKM.1(SYM)
FCS_CKM.1(RSA)
FCS_CKM.1(DSA)
FCS_CKM.4 FCS_CKM.4
FCS_CKM.4 FCS_CKM.1 FCS_CKM.1(SYM), FCS_CKM.1(RSA)
FCS_CKM.1(DSA), FCS_CKM_EXT.1(ECDSA)
FCS_COP_EXT.1(SGN) [FDP_ITC.1 or
FDP_ITC.2 or
FCS_CKM.1]
FCS_CKM.1(RSA)
FCS_CKM.1(DSA)
FCS_CKM.4 FCS_CKM.4
FCS_COP.1(NET) FCS_CKM.1 FCS_CKM.1(SYM)
FCS_CKM.1(RSA)
FCS_CKM.1(DSA)
FCS_CKM.4 FCS_CKM.4
FCS_COP_EXT.1(CRYPT
O-ENC)
FCS_CKM.1 FCS_CKM.1(SYM)
FCS_CKM.4 FCS_CKM.4
FCS_COP_EXT.1(CRYPT
O-MD)
FCS_CKM.1 not applicable, since no keys are required
for hashing
FCS_CKM.4 not applicable, since no keys are required
for hashing
FCS_COP_EXT.1(CRYPT FCS_CKM.1 FCS_CKM.1(RSA)
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Requirement
Dependencies Resolution
O-SGN) FCS_CKM.1(RSA)
FCS_CKM.1(DSA)
FCS_CKM_EXT.1(ECDSA)
FCS_RNG.1 No
dependencies.
FDP_ACC.1(PSO) FDP_ACF.1 FDP_ACF.1(PSO-UNIX)
FDP_ACF.1(PSO-MVS)
FDP_ACF.1(PSO-LDAP)
FDP_ACC.1(TSO) FDP_ACF.1 FDP_ACF.1(TSO)
FDP_ACF.1(PSO-MVS) FDP_ACC.1 FDP_ACC.1(PSO)
FMT_MSA.3 FMT_MSA.3(PSO)
FDP_ACF.1(PSO-UNIX) FDP_ACC.1 FDP_ACC.1(PSO)
FMT_MSA.3 FMT_MSA.3(PSO)
FDP_ACF.1(PSO-LDAP) FDP_ACC.1 FDP_ACC.1(PSO)
FMT_MSA.3 FMT_MSA.3(PSO)
FDP_ACF.1(TSO) FDP_ACC.1 FDP_ACC.1(TSO)
FMT_MSA.3 FMT_MSA.3(TSO)
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Security Functional
Requirement
Dependencies Resolution
FDP_ETC.1 (Labeled
Security Mode only)
[FDP_ACC.1 or
FDP_IFC.1]
FDP_ACC.1(PSO)
FDP_ETC.2(LS)
(Labeled Security
Mode only)
FDP_IFC.1 FDP_IFC.2(LS) (Labeled Security Mode only)
FDP_IFC.2(LS) (Labeled
Security Mode only)
FDP_IFF.1 FDP_IFF.2(LS) (Labeled Security Mode only)
FDP_IFC.2(NI) FDP_IFF.1 FDP_IFF.1(NI)
FDP_IFF.1(NI) FDP_IFC.1 FDP_IFC.2(NI)
FMT_MSA.3 FMT_MSA.3(NI)
FDP_IFF.2(LS) (Labeled
Security Mode only)
FDP_IFC.1 FDP_IFC.2(LS) (Labeled Security Mode only)
FMT_MSA.3 FMT_MSA.3(LS) (Labeled Security Mode
only)
FDP_ITC.1(LS) (Labeled
Security Mode only)
FDP_IFC.1 FDP_IFC.2(LS) (Labeled Security Mode only)
FMT_MSA.3 FMT_MSA.3(LS) (Labeled Security Mode
only)
FDP_ITC.2 FDP_ACC.1 FDP_ACC.1(PSO)
FDP_ACC.1(TSO)
FDP_IFC.1 FDP_IFC.2(NI)
FTP_ITC.1 FTP_ITC.1
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Security Functional
Requirement
Dependencies Resolution
FTP_TDC.1 FPT_TDC.1
FDP_ITC.2(LS) (Labeled
Security Mode only)
FDP_IFC.1 FDP_IFC.2(LS) (Labeled Security Mode only)
FTP_ITC.1 FTP_ITC.1
FPT_TDC.1 FPT_TDC.1(LS) (Labeled Security Mode
only)
FDP_RIP.2 No
dependencies.
FDP_RIP.3 No
dependencies.
FIA_AFL.1 FIA_UAU.1 FIA_UAU.1
FIA_ATD.1(HU) No
dependencies.
FIA_ATD.1(TU) No
dependencies.
FIA_ATD.1(EIA) No
dependencies.
FIA_ATD.1(LS) (Labeled
Security Mode only)
No
dependencies.
FIA_SOS.1 No
dependencies.
FIA_UAU.1 FIA_UID.1 FIA_UID.1
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Security Functional
Requirement
Dependencies Resolution
FIA_UAU.5 No
dependencies.
FIA_UAU.7 FIA_UAU.1 FIA_UAU.1
FIA_UAU.8(EIA) FTP_ITC.1 FTP_ITC.1
FIA_UID.1 No
dependencies.
FIA_UID.3(EIA) FTP_ITC.1 FTP_ITC.1
FIA_USB.1(LS) (Labeled
Security Mode only)
FIA_ATD.1 FIA_ATD.1(LS) (Labeled Security Mode
only)
FIA_USB.2 FIA_ATD.1 FIA_ATD.1(HU)
FIA_ATD.1(TU)
FMT_MSA.1(PSO) FDP_ACC.1 FDP_ACC.1(PSO)
FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MSA.1(TSO) FDP_ACC.1 FDP_ACC.1(TSO)
FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MSA.1(LS) FMT_IFC.1 FDP_IFC.2(LS) (Labeled Security Mode only)
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Security Functional
Requirement
Dependencies Resolution
(Labeled Security
Mode only)
FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MSA.3(PSO) FMT_MSA.1 FMT_MSA.1(PSO)
FMT_SMR.1 FMT_SMR.1
FMT_MSA.3(TSO) FMT_MSA.1 FMT_MSA.1(TSO)
FMT_SMR.1 FMT_SMR.1
FMT_MSA.3(NI) FMT_MSA.1 FMT_MTD.1(NI) is specified to require the
management of security attributes for the
Network Information Flow Control Policy,
just as a potential FMT_MSA.1(PF) would
have been specified. However, the Network
Information Flow Control Policy is not
required to be enforced when managing
the security attributes, as the management
aspect of the packet filtering functionality
is not protected by the packet filter.
Therefore, FMT_MSA.1 is not applicable and
is replaced with FMT_MTD.1(NI).
FMT_SMR.1 FMT_SMR.1
FMT_MSA.3(LS)
(Labeled Security
Mode only)
FMT_MSA.1 FMT_MSA.1(LS) (Labeled Security Mode
only)
FMT_SMR.1 FMT_SMR.1
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Security Functional
Requirement
Dependencies Resolution
FMT_MSA.4(PSO) FDP_ACC.1 FDP_ACC.1(PSO)
FMT_MTD.1(AE) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(AS) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(AT) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(AF) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(NI) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(NI2) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(IAT) FMT_SMR.1 FMT_SMR.1
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Security Functional
Requirement
Dependencies Resolution
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(IAF) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(IAU) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(IAU-AUTH) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(EIA) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(CRYPTO1) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(CRYPTO2) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 FMT_SMF.1
FMT_MTD.1(ADD) FMT_SMR.1 FMT_SMR.1
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Security Functional
Requirement
Dependencies Resolution
FMT_SMF.1 FMT_SMF.1
FMT_REV.1(OBJ) FMT_SMR.1 FMT_SMR.1
FMT_REV.1(USR) FMT_SMR.1 FMT_SMR.1
FMT_SMF.1 No
dependencies.
FMT_SMR.1 FIA_UID.1 FIA_UID.1
FPT_STM.1 No
dependencies.
FPT_TDC.1 No
dependencies.
FPT_TDC.1(LS)
(Labeled Security
Mode only)
No
dependencies.
FTA_SSL.1 FIA_UAU.1 FIA_UAU.1
FTA_SSL.2 FIA_UAU.1 FIA_UAU.1
FTP_ITC.1 No
dependencies.
Table 10: TOE SFR dependency analysis
7.2.4 TSF Rationale
The following table maps the security functional requirements to the security functions as
defined in the TOE summary specification to show that all security functional requirements
are addressed by the security functions.
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SFR Security Functions
FAU_GEN.1 Section Generation of audit records explains how audit
records are generated. This section also explains the
structure of the audit records.
FAU_GEN.2 Section Generation of audit records explains the information
contained in the audit records. Tools to export audit records
in human-readable format are mentioned in this section, too.
FAU_SAR.1 Section User roles and attributes and section AUDITOR and
group-AUDITOR explain the auditor role. Section Protection of
the audit trail describes the purpose of the audit dump
programs that read audit records from the audit trail and
store them in a data set where they can be assessed.
FAU_SAR.2 Section Protection of the audit trail explains how to protect
the audit trail from unauthorized access.
FAU_SAR.3 Section Generation of audit records explains how to search
the audit records. Section Using MVS Data Sets for SMF and
Using a System Log Stream for SMF explain the IFASMFDP
and IFASMFDL programs for unloading selected audit records.
FAU_SEL.1 Sections Audit configuration and management and AUDITOR
and group-AUDITOR explain how the auditor role can
configure the events that are audited. These chapters also
explain that the owner of a profile can define which events
related to the profile are audited.
FAU_STG.1 Section Protection of the audit trail explains how to protect
the audit trail from unauthorized access.
FAU_STG.3 Section Using MVS Data Sets for SMF explains how the
operator is informed about the fact that a SMF data set is full
and the TOE has switched to the next non-full SMF data set.
FAU_STG.4 Section Audit configuration and management explains how
the TOE prevents the loss of audit data by halting the system
on audit trail exhaustion.
FCS_CKM.1(SYM),
FCS_CKM.2(NET)
Section System SSLSystem SSL explains the use of the
SSL/TLS protocols for the protection of communication links.
Section Communications Server explains the use of the IPSec
protocol for the protection of communication links by
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reference to the appropriate IETF standards. This discussion
includes (by reference to the IETF standards) usage of HMAC-
SHA-1 for integrity protection of the communication links.
Section IBM Ported Tools for z/OS (OpenSSH) explains the use
of the SSH protocols for the protection of communication
links.
Section Network Authentication Service explains the use of
the Kerberos and GSSAPI protocols for the protection of
communication links.
FCS_CKM.1(DSA),
FCS_CKM.1(RSA)
Generation of RSA and DSA host keys for SSH is explained in
IBM Ported Tools for z/OS (OpenSSH)
The generation of RSA and DSA public/private key pairs using
the RACDCERT command is explained in section Digital
Certificates, Key Rings, and Certificate Mappings in RACF and
PKCS#11 Cryptographic Tokens.
FCS_CKM_EXT.1(ECDSA) The provision of ECDSA via ICSF on z/OS executing on a z114
or z196 system (which uses a CEX3C coprocessor if
available) for the use by an application is explained in
chapter 8.1.10 Implementation of cryptographic functions,
section 8.1.10.1 Cryptographic Functions for Application Use
FCS_CKM.4 As pointed out in the SFR's application note, cryptographic
keys for SSL/TLS, Kerberos, SSH, and IPsec sessions are
protected by the TOE against unauthorized access and are
destroyed by the object re-use functions of the TOE. The
object reuse function is described in Object reuse.
FCS_COP_EXT.1(SGN) Signature creation and verification is explained for the
different usage scenarios as follows:
• TLS/SSL: System SSL
• IPSec ISAKMP session establishment: Communications
Server by reference to the applicable RFCs (2408 and
others) and mentioning that IKE daemons can use NSS
to perform RSA signature generation and verification.
• RACDCERT: Digital Certificates, Key Rings, and
Certificate Mappings in RACF and PKCS#11
Cryptographic Tokens
• PKI Services PKI Services
In addition, Communications Server explains that signature
creation and verification can also be performed through the
Network Security Services (NSS) on behalf of trusted remote
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XMLAppliance clients.
FCS_COP.1(NET) Cryptographic operations are explained for the different
protocols in the respective TSS sections for these protocols:
• TLS/SSL: System SSL
• IPSec: Communications Server
• SSH: IBM Ported Tools for z/OS (OpenSSH)
• Kerberos: Network Authentication Service
FCS_COP_EXT.1(CRYPTO
-ENC)
The provision of 3DES and AES as well as RSA via ICSF is
explained in chapter 8.1.10 Implementation of Cryptographic
Functions, section 8.1.10.1 Cryptographic Functions for
Application Use. ICSF will use CPACF for 3DES and AES and
will use a CryptoExpress3 coprocessor for RSA if such a
coprocessor is installed and available.
FCS_COP_EXT.1(CRYPTO
-MD)
The provision of SHA1, SHA-256 and SHA-512 via ICSF is
explained in chapter 8.1.10 Implementation of Cryptographic
Functions, section 8.1.10.1 Cryptographic Functions for
Application Use. ICSF will use CPACF for those algorithms
provided the processor provides instructions for those
algorithms.
FCS_COP_EXT.1(CRYPTO
-SGN)
The provision of DSA, RSA, and ECDSA via ICSF is explained
in chapter 8.1.10 Implementation of Cryptographic Functions,
section 8.1.10.1 Cryptographic Functions for Application Use.
ICSF will use a CryptoExpress3 coprocessor if installed and
available for RSA. In case z/OS is executing on a z114 or z196
processor and a CryptoExpress3 coprocessor is installed,
ICSF will also use the coprocessor for the ECDSA function.
FCS_RNG.1 Random numbers are provided either through the TOE
environment by the functionality of the crypto cards, or by
the TOE's software. The two software components providing
random numbers for key generation are System SSL and
OpenSSH. An analysis of the functionality and quality of the
random number generators in these components is provided
in a separate document.
FDP_ACC.1(PSO) The general operation of access control is explained in
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FDP_ACC.1(TSO) section Access control principles. The possible access rights
for discretionary access control are explained in section DAC
for MVS resources. Since access control to TCP/IP stacks,
addresses and ports is managed with RACF profiles, this
explanation is also applicable to these transient objects.
The protected resources are explained in section Protected
resources.
Unix and LDAP objects and their access control attributes are
explained in DAC for UNIX objects and DAC for LDAP LDBM
objects, respectively
FDP_ACF.1(PSO-MVS) Discretionary access control for z/OS MVS objects is
explained in section Discretionary Access Control (DAC for
MVS resources and DAC for System Logger Objects in the
LOGSTRM class), listing all the different types of objects and
the specifics of their access control mechanisms.
FDP_ACF.1(PSO-UNIX) Section DAC for UNIX objects explains access control for z/OS
UNIX objects. The access control algorithm for persistent
objects is found in subsection Algorithm to check DAC access
to UNIX file system objects.
FDP_ACF.1(PSO-LDAP) Section DAC for LDAP LDBM objects explains access control
to objects in the LDAP LDBM database.
FDP_ACF.1(TSO) Section DAC for UNIX objects explains access control for z/OS
UNIX objects. The access control algorithm for temporary
objects is found in subsection Algorithm to check DAC access
to UNIX IPC objects.
FDP_ETC.1 (Labeled
Security Mode only)
Export of non-labeled user data is performed by tapes or
through network connections. It is not mentioned explicitly
that those connections can be used for this purpose, but this
should be clear. Access control to these export channels in
explained in section DAC for MVS resources.
FDP_ETC.2(LS) (Labeled
Security Mode only)
Export of labeled data is explained in section Mandatory
Access Control (Labeled Security Mode only).
FDP_IFC.2(LS) (Labeled
Security Mode only)
FDP_IFF.2(LS) (Labeled
Security Mode only)
The mandatory access control policy is explained in section
Mandatory Access Control (Labeled Security Mode only).
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FDP_IFC.2(NI)
FDP_IFF.1(NI)
The packet filtering functions of the Communications Server
are explained in section Communications Server in the
paragraphs on Packet filtering
FDP_ITC.2
FDP_ITC.1(LS) (Labeled
Security Mode only)
Import of unlabeled user data is the inverse of export and is
explained in the same sections as the export.
FDP_ITC.2(LS) (Labeled
Security Mode only)
Import of labeled user data is the inverse of export and is
explained section Mandatory Access Control (Labeled
Security Mode only).
FDP_RIP.2
FDP_RIP.3
Object reuse is described in section Object reuse.
FIA_AFL.1 The system-wide attribute REVOKE for the number of failed
consecutive authentication attempts is explained in Password
Quality and Password Phrase Quality. The effect of a user ID
being revoked is described in subsection REVOKE of RACF
Roles.
FIA_ATD.1(HU)
FIA_ATD.1(EIA)
User attributes for human users are defined in section User
and group management, subsections Definition of users and
groups, User profiles, Defining Kerberos Users, LDAP LDBM
Users, Group Profiles, LDAP LDBM GroupsLDAP LDBM Groups
and User roles and attributes,
FIA_ATD.1(TU) Technical users are explained in section .. Other than that,
technical users have the same attributes as human users
(see the entry FIA_ATD.1(HU) above).
FIA_ATD.1(LS) (Labeled
Security Mode only)
Labels as users attributes are described in sectkion
Mandatory Access Control (Labeled Security Mode only).
FIA_SOS.1 The password and password phrase specifics are defined in
section Password Quality and Password Phrase Quality.
FIA_UAU.1 User authentication is explained in section Identification and
Authentication, subsections Authentication function, RACF
Passwords and Password Phrases, RACF PassTickets,
Authentication via Client Digital Certificates, Authentication
via Kerberos, Authentication by trusted servers,
Authentication Method Summary, Handling of Groups During
Authentication and Authentication-related differences
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between z/OS UNIX and typical non-z/OS UNIX systems.
FIA_UAU.5 Authentication using passwords and password phrases is
explained in section RACF Passwords and Password Phrases.
Authentication using digital certificates is explained in
section Authentication via Client Digital Certificates.
Authentication using Kerberos tickets is explained in section
Authentication via Kerberos.
Authentication using RACF PassTickets is explained in section
RACF PassTickets.
FIA_UAU.7 Section RACF Passwords and Password Phrases describes
that passwords are not displayed when entered during
authentication.
FIA_UAU.8(EIA)
FIA_UID.3(EIA)
In section Authentication function, the XMLAppliance
discipline explains how trusted, authenticated XMLAppliance
clients can request an authentication decision from the TOE
based on userIDs and passwords or PassTickets presented to
RACF.
FIA_UID.1 User identification is explained in Identification and
Authentication.
FIA_USB.1(LS) (Labeled
Security Mode only)
The user sensitivity level bound to subjects while the TOE
operates in Labeled Security Mode is explained in Mandatory
Access Control (Labeled Security Mode only).
FIA_USB.2 User subject binding for z/OS is explained in section
Identification and Authentication, which describes protected
user IDs in section Protected user IDs. Specifics of the z/OS
UNIX su command are explained in section Authentication-
related differences between z/OS UNIX and typical non-z/OS
UNIX systems, exemptions for started tasks in section
Started procedures.
FMT_MSA.1(PSO),
FMT_MSA.1(TSO)
Management of object security attributes is explained in
section Resource management (and subsections) where the
different RACF profiles and their management is described,
along with descriptions for z/OS UNIX objects and LDAP LDBM
objects. Section RACF configuration and management
explains the RACF configuration.
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FMT_MSA.1(LS)
(Labeled Security Mode
only)
Management of security labels being restricted to users with
the SPECIAL attribute is described in section Mandatory
Access Control (Labeled Security Mode only).
FMT_MSA.3(PSO)
FMT_MSA.3(TSO)
Default values for the access control are defined in the UACC
attribute in the resource profiles as explained in section
Resource management (and subsections) in the description
of the resource profiles. Defaults for z/OS UNIX and LDAP
LDBM objects are discussed in sections z/OS UNIX file system
resources and LDAP LDBM resources.
FMT_MSA.3(NI) In section Network configuration and management, the
configuration files for the Communications Server are
described.
FMT_MSA.3(LS)
(Labeled Security Mode
only)
Default values for the security label are defined in the
SECLABEL attribute in the resource profiles as explained in
section Resource management (and subsections) in the
description of the resource profiles and in section z/OS UNIX
file system resources for z/OS UNIX objects.
FMT_MSA.4(PSO) The inheritance of MVS object attributes from the
corresponding RACF profile is described in section
Discretionary Access Control. The inheritance mechanism for
LDAP LDBM objects is described in DAC for LDAP LDBM
objects
FMT_MTD.1(AE) Management of audited events is explained in section Audit
configuration and management and in the section on the
AUDITOR role (AUDITOR and group-AUDITOR).
FMT_MTD.1(AF)
FMT_MTD.1(AS)
FMT_MTD.1(AT)
Audit trail management is explained in section Audit
configuration and management. Halting the system in case
of audit trail exhaustion is described in Using MVS Data Sets
for SMF. The threshold to warn about audit trail exhaustion is
implemented by the process of switching audit data sets and
dumping them to external storage, as described in Using
MVS Data Sets for SMF. The management of Log Streams is
described in section Security Management for System Logger
Log Streams.
FMT_MTD.1(NI) Configuration and management of IPSec configuration data
via the command line is explained in section
Communications Server ipsec Command Interface.
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FMT_MTD.1(NI2) Configuration and management of additional IPSec
configuration data via network interfaces is explained in
section Communications Server Network Management
Interface.
FMT_MTD.1(IAF)
FMT_MTD.1(IAT)
The system-wide attribute REVOKE for the number of failed
consecutive authentication attempts is explained in Password
Quality and Password Phrase Quality. The effect of a user ID
being revoked is described in subsection REVOKE of RACF
Roles. The management authorities to resume revoked users
and/or to reset their passwords is described in section
Definition of users and groups.
FMT_MTD.1(IAU)
FMT_MTD.1(IAU_AUTH)
FMT_MTD.1(EIA)
Management of user attributes is explained in section User
and group management, subsections Definition of users and
groups, User profiles, Defining Kerberos Users and LDAP
LDBM Users.
FMT_MTD.1(CRYPTO1) Management of cryptographic keys is explained in section
Communication security, Digital Certificates, Key Rings, and
Certificate Mappings in RACF and PKCS#11 Cryptographic
Tokens and PKI Services.
FMT_MTD.1(CRYPTO2) Configuration and management of digital certificates is
explained in section PKI Services. Management of the
mapping to RACF user is explained in section Digital
Certificates, Key Rings, and Certificate Mappings in RACF and
PKCS#11 Cryptographic Tokens.
FMT_MTD.1(ADD) Configuration and management of additional TOE
configuration data is explained throughout section Network
configuration and management. Section Authentication by
trusted servers describes specifies of the configuration of the
HTTP server , FTP server, CIM server, and LDAP server. PKI
Services administration is described in section Security
Administration for PKI Services.
FMT_REV.1(OBJ) Revocation of object attributes is explained as part of the
management of access control to objects in sections (or
subsections of) Discretionary Access Control, Mandatory
Access Control (Labeled Security Mode only) and
Discretionary Access Control.
FMT_REV.1(USR) Revocation of user attributes is explained as part of the
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management of user attributes in section User Revocation
and the subsection REVOKE of RACF Roles.
FMT_SMF.1 See SFRs FMT_MTD.1(x)
FMT_SMR.1 The roles are explained in sections User roles and attributes.
FPT_STM.1 The time mechanism is explained in section Processor
features.
FPT_TDC.1
FPT_TDC.1(LS) (Labeled
Security Mode only)
The capability to provide inter-TSF data consistency for the
RACF database and the extended attributes of z/OS UNIX file
system objects is explained with the description of the
structure of the RACF database and their profiles in section
Management(and subsections) and the description of the
extended attributes for z/OS UNIX file system objects in
sections UNIX file system objects, Mandatory Access Control
(Labeled Security Mode only) and z/OS UNIX file system
resources, which allows consistent interpretation of this data
in different instantiations of the TOE. This also covers
security labels.
FTA_SSL.1
FTA_SSL.2
Trivially satisfied: As stated in Session Locking, the TOE does
not have direct interactive human connections, since the
hardware does not allow direct connections of 3270
terminals any more, so session locking is irrelevant to this
TOE.
FTP_ITC.1 The different ways of establishing a trusted channel
(SSL/TLS, IPSec, SSH, Kerberos are explained in section
Communication security
Table 11: Mapping security functional requirements to security functions
7.2.5 Mutual support of the security functions
This section demonstrates that the TOE security functions are mutually supportive by
showing how the individual functions are interrelated.
Identification and authentication is a prerequisite for discretionary and (in Labeled Security
Mode) mandatory access control as well as the security management functions that require
the user to have the required privileges to perform the management activities. It also is a
prerequisite to auditing by provision of a unique and reliable reference to a user causing an
audit event. Identification and authentication is supported by access control that protects
the user and group profiles (including the authentication information) against unauthorized
access and modification. In addition identification and authentication is supported by
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security management that defines user with their credentials and assigns initial
authentication information to them.
Discretionary access control supports identification and authentication (as explained) above
and also supports audit by protecting the audit data sets against unauthorized access,
supports security management by protecting security management information stored in
data sets or files and by ensuring that the user performing management functions have the
required privileges. Access control also supports communication security by protecting
access to the TCP/IP stack in general as well as individual network ports.
Labeled Security Mode: Mandatory access control is implemented in the TOE in addition to
discretionary access control. Mandatory access control is supported by identification and
authentication as well as security management with respect to the definition of security
labels, the assignment of labels to objects and the assignment of security classification to
users.
Communication security provides support for identification and authentication because it
allows to protect the transfer of authentication information. It also supports discretionary
access control to communication links, because the confidentiality and integrity protection
provided by the cryptographic functions prohibit spoofing attacks.
Security management is required to manage the users, groups and the privileges of users.
This is supporting identification and authentication as well as access control. Different
aspects of security management support each other. For example user and group
management supports the management of access control, because the definition of access
rights can be simplified by defining access on a group level and assign users that require
access to the appropriate groups. Security management also supports auditing because it
allows to define the events to be audited based on individual users, individual protected
objects, privileges of the users, type of event, and (in Labeled Security Mode) security label.
In addition the security management of the audit data (especially dumping the SMF data
sets when they get full) also supports audit. Security management also includes the
management of access rights including (in Labeled Security Mode) the definition of the
security labels and the definition how they get printed on a printer that supports multiple
labels. Management of discretionary access rights can be performed by users with the
required privileges and the management of those privileges is part of the user and group
management. This structure allows delegation of some management functions to users with
privileges limited to the scope of a group. Security management also supports
communication security by providing the ability to configure the different protection
mechanisms SSL/TLS, IPSec, SSH, Kerberos, and AT-TLS.
Auditing is a secondary security function that does not provide direct support for other
security functions. Auditing provides indirect support to other security functions, because it
allows identification of security problems and allows definition of appropriate measures (in
the TOE configuration or the TOE environment) to prevent those events in the future.
Object reuse supports access control to avoid that users get access to information related to
system internals like authentication information(passwords) and access information in
contradiction to the mandatory access control. Object reuse therefore supports TOE self-
protection, identification and authentication and (in Labeled Security Mode) mandatory
access control.
TOE self-protection supports all other security functions to ensure that they can not be
tampered with or bypassed.
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7.3 Security Assurance Requirements
The following SAR was included from the OSPP base. It does not put an additional
requirement on the product but requires the evaluator to check that all ST author notes from
the PP have bean dealt with in this security target.
The security assurance requirements for the TOE are the Evaluation Assurance Level 4
components, augmented by ALC_FLR.3, as specified in [CC] part 3.
The following table shows the Security assurance requirements for the TOE that are
specifically instantiated for the TOE through the operations on assurance components
allowed in CC part 3: iteration (Iter.), refinement (Ref.), assignment (Ass.) and selection
(Sel.).
Security
assurance
class
Security
assurance
requirement
Security
assurance
component
Source Operations
Iter. Ref. Ass. Sel.
ASE Security
Target
evaluation
ASE_CCL.1(CCR)
Conformance claims
ASE_CCL.1 CC Part 3 No Yes No No
Table 12: Security assurance requirements for the TOE
7.3.1 Security Target evaluation (ASE)
7.3.1.1 Conformance claims (ASE_CCL.1(CCR))
Content and presentation elements:
ASE_CCL.1.10C The conformance claim rationale shall demonstrate that the statement of
security requirements is consistent with the statement of security
requirements in the PPs including the statements marked as “ST-Author
Note” and the specification given in section 8.1 of the OSPP base for
which conformance is being claimed.
Application note: ASE_CCL.1 specified in CC Part 3 is refined as follows:
All Developer Action Elements, Content and Presentation Elements,
Evaluator Action Elements remain unaltered, except for ASE_CCL.1.10C
as refined above.
7.4 Security Assurance Requirements Rationale
The evaluation assurance level has been chosen commensurate with the threat environment
that is experienced by typical consumers of the TOE. In addition, the evaluation assurance
level has been augmented with ALC_FLR.3 commensurate with the augmented flaw
remediation capabilities offered by the developer beyond those required by the evaluation
assurance level.
The assurance measures and how they are satisfied are explained in the table in section
"TOE Assurance Measures". The authors of this Security Target view this table as sufficient
justification for the individual assurance measures.
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8 TOE Summary Specification
8.1 TOE Security Functionality
This chapter provides a summary of the security functions of z/OS that are subject to the
evaluation. z/OS has more security functions than described in this chapter; only those that
implement the security requirements claimed in chapter 7are described here.
The chapter also provides some overview material required for a basic understanding how
the security functions work. Those details of the security functions that are the focus of the
evaluation are marked in curly braces using an identifier for the security function and a
number.
8.1.1 Overview of the TOE architecture
z/OS is an operating system that runs on the IBM z/Architecture processors. Those
processors provide a separate problem and supervisor state and memory protection
functions that allow z/OS to prohibit direct access from untrusted applications to I/O devices,
protected memory areas used by the TOE, and memory areas used by other applications.
The underlying firmware also allows the definition of separate logical partitions where
several instances of the TOE can execute in parallel on the same hardware. The TOE may
also be loaded in one logical partition while other non-TOE software is loaded in other logical
partitions. The logical partitioning function is part of the TOE environment and has been
evaluated separately.
The TOE provides an interface to applications by allowing them to request TOE services.
The TOE provides the following security functions:
i. Identification and authentication
ii. Discretionary Access Control based on access control lists associated with objects
iii. In Labeled Security Mode: Mandatory Access Control based on security attributes of
subjects and objects
iv. Management functions to administer auditing, discretionary access control, and (in
Labeled Security Mode) mandatory access control, as well as users and groups with
their related attributes
v. Secure communication
vi. Auditing
vii. Object reuse
viii.TOE self-protection functions based on security features provided by the underlying
hardware including memory protection and the provision of a privileged state that
allows the TOE to reserve and protect a domain for its own execution.
The TOE itself is logically structured into the following major units:
i. The Hardware Configuration Definition (HCD), which mirrors the IOCDS definition of
the underlying abstract machine.
ii. The Base Control Program (BCP), which is responsible for handling supervisor call
interrupts, program call interrupts, and all other interrupts, and task scheduling and
memory management, including the management of address spaces
iii. The Data Facility Storage Management Subsystem (DFSMS), which is responsible for
accessing and managing disk and tape devices, including the data sets on those
devices
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iv. The Communications Server, which is responsible for network communication using
SNA- or IP-based protocols , and which provides TN3270, FTP, telnet, rsh, IKE,
Network Security Services (NSS), Centralized Policy, and DCAS servers.
v. The Job Entry Subsystem (JES2), which is responsible for scheduling jobs and
handling spool files (for the purpose of the evaluation, the SDSF display facility is
considered to be part of JES2)
vi. The UNIX System Services, which provides UNIX programming, user interfaces, and
rlogin support. For the purposes of this ST, zFS and HFS are considered to be part of
UNIX System Services.
vii. The Resource Access Control Facility (RACF), which is the central system for
discretionary and mandatory access control to resources
viii.The Time Sharing Option Extensions (TSO/E) system, which is responsible for
handling of commands issued by users at TSO/E terminals
ix. The Print Services Facility (PSF) provides services for printing of output, and prints
proper security labels on pages.
x. System SSL, which provides SSL- and TLS-related functions for selected TOE
components and for application programs.
xi. IBM Ported Tools for z/OS which provides OpenSSH functions (e.g, sshd, scp, sftp).
The evaluated version includes the following security-relevant features:
a. OpenSSH 5.0p1
b. OpenSSL 0.9.8k (statically linked; not available to applications)
c. zlib 1.2.3 (statically linked; not available to applications)
d. sudo 1.7.2p2 (provided in the IBM Ported Tools for z/OS: Supplementary
Toolkit for z/OS Feature), which allows specified users to run specified
commands under a different identity, as configured by the administrator.
xii. The z/OS Network Authentication Service and associated GSSAPI programming
services that provides authentication and message privacy and integrity functions.
xiii.The IBM HTTP Server.
xiv.The z/OS Cryptographic Services Integrated Cryptographic Services Facility, which
provides management of secure crypto keys used with the CryptoExpress3 hardware
card, and management of the cryptographic hardware. It also implements storage,
retrieval, and maintenance of information contained in PKCS#11 cryptographic
tokens and provides cryptographic services for selected TOE components and for
applications running on the TOE.
xv. z/OS Cryptographic Services PKI Services, which provides digital certificate
management (CA and RA) functions.
xvi.z/OS Network File System (NFS), which provides access to MVS data sets and UNIX
files to clients over the TCP/IP network.
xvii. IBM Tivoli Directory Server (also called z/OS LDAP Server in this ST), which
provides LDAP support and also an interface allowing remote administration of RACF
users and groups in non-MLS environments.
xviii. IBM z/OS Common Information Model (CIM) Server, which provides CIM data and
services to help manage z/OS in a distributed network, and is based on OpenPegasus
CIM Server.
xix.The System REXX (AXR) server address space which can run REXX execs upon
request from other parts of the TOE. Such execs run using the identity of the
requester, and run in an authorized state (unlike REXX execs run in batch, TSO, or
z/OS UNIX shell environments).
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The TOE itself consists of a “nucleus” operating in the supervisor state of the underlying
abstract machine and a set of “trusted processes” that either also operate in supervisor
state or operate as “authorized programs”. Those authorized programs start their operation
in problem state, but can switch into supervisor state, operate with storage key 0, or both,
so are therefore not limited in their capabilities by any element of the system security
policy. Therefore, all authorized programs allowed to be executed in the evaluated
configuration are considered to be part of the TOE. Additionally, any program running with
UID(0) or with access to the FACILITY class resources BPX.SUPERUSER, BPX.DAEMON, or
BPX.SERVER, or with access to any UNIXPRIV class resources named SUPERUSER.function-
name, or with access to any PTKTDATA class profiles named IRRPTAUTH.function-name, are
considered “authorized” for this evaluation, and thus are also considered to be part of the
TOE.
More information on how the TOE identifies, manages, and protects authorized programs
can be found in Authorized programs.
8.1.1.1 Main trusted subsystems of the evaluated configuration
Some programs are started with authorization (see also Authorized programs) during system
startup. Those include the Job Entry Subsystem (JES2), PSF, the Time Sharing Option
Extensions (TSO/E) subsystem, the Communication Subsystem (CS), and the z/OS UNIX
System Services.
Job Entry Subsystem (JES2)
The Job Entry Subsystem is responsible for starting jobs that have been entered at remote or
local entry stations, submitted by TSO or UNIX users or submitted by batch jobs themselves.
A job consists of a set of individual job steps described in the Job Control Language (JCL).
There, the name of the job, the user ID the job will have during execution (usually inherited
from the submitting user), the data sets used by each job step, and the first program to be
started for each job step are defined.
JES2 is responsible for scheduling those jobs, that is, for transforming the JCL statements
into internal control blocks and initiating each job step in cooperation with the “initiator”. As
described above, a job step may execute with the authorization bit set in the Job Step
Control Block (JSCB) if the conditions mentioned above are satisfied.
JES2 uses RACF to authenticate users. If they are not already authenticated by another
subsystem, users need to specify their passwords in the job card, which is the first JCL
statement in a job. JES2 also uses RACF to control access to data sets and printers.
JES2 is responsible for managing spool files for job input and job output. JES2 also manages
printers attached to it. In Labeled Security Mode and in the case of a multilevel printer
device, JES2 in cooperation with the printer system ensures that each page of printer output
is marked with the security label of the job step that produced the output.
Time Sharing Option Extensions (TSO/E)
TSO/E is the main dialog system within a primary user interface to the z/OS system. This
interface provides many capabilities such as allowing users to execute commands and
programs as well as write programs in a high-level procedural language known as REXX.
VTAM creates a separate address space for each TSO/E user. TSO/E requires user
authentication before allowing users to issue TSO commands, execute programs, or submit
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jobs to JES2. RACF provides the user authentication and resource access controls for TSO/E
users, as for all other users on the system.
TSO commands and services can also run outside of a TSO/E login environment, such as in
batch jobs or in UNIX processes. In such cases, TSO/E has not performed the authentication
functions, which took place either in JES or in the UNIX processing that established the
process. However, all access checking for resources used by the TSO commands and
services happens just as for commands and services invoked in the standard TSO/E login
environment.
Communications Server
z/OS provides networking functions with the Communications Server. This subsystem
provides support for network communication using the IBM SNA protocols and the TCP/IP
protocol suite. APIs for both protocol stacks are provided. For IP, both IPv4 and IPv6 are
supported. For the evaluated configuration, use of SNA networking by user programs has
been excluded. Only those parts of SNA that are required for TN3270 are part of the TOE.
Those parts do not export a direct interface for the use by untrusted programs.
z/OS UNIX System Services
z/OS also provides users and programs with a UNIX environment. RACF-defined users who
also have a UNIX UID and whose default group (at least) has a GID can use this environment
to operate in a UNIX shell environment and use UNIX commands and program library
interfaces.
Additionally, users defined as UNIX users can also use UNIX-based programs, and access
UNIX data, while running in other environments, such as TSO/E or batch, and users running
in a UNIX environment can access non-UNIX data (e.g., MVS data sets).
RACF is used by the UNIX system services to:
 authenticate users
 control access to UNIX files and directories
 control access to UNIX IPC objects
UNIX files have the traditional access permission bits and POSIX-compatible access control
lists. To manage an ACL for a file, one must either be the file owner or have superuser
authority (UID=0 or have READ access to SUPERUSER.FILESYS.CHANGEPERMS in the
UNIXPRIV class). In Labeled Security Mode, UNIX files and directories are also subject to the
mandatory access control function of the TOE. File permission bits and access control lists
are stored with the files as part of the UNIX file system. In all attempts to access a UNIX file,
the UNIX system services will call RACF and provide the permission bits, access control list
and (in Labeled Security Mode) security label as an additional input to the call.
UNIX IPC objects are controlled by the access permission bits for IPC objects and (in Labeled
Security Mode) the mandatory access control rules defined by RACF.
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In Labeled Security Mode: For full support of mandatory access control, the evaluated
configuration only supports zFS as a UNIX file system. A read-only hierarchical file system
(HFS) can also be used if the contained data is at the same security level.
Print Services Facility
z/OS provides printing functions with JES2 and PSF. These subsystems provide support for
printing output on a large variety of print peripherals. In Labeled Security Mode, PSF must be
used in conjunction with JES2 to enforce printing of security labels on all pages of print jobs
containing labeled data.
8.1.2 Identification and Authentication
8.1.2.1 Authentication function
A user can interact with the TOE in one of the following ways:
 As a TSO user
 As an operator at a console
 By submitting a job to be initiated and scheduled by the Job Entry Subsystem (JES2)
 As a UNIX user, including access via the UNIX shell or as a client of a UNIX-based
server such as FTP, HTTP, SSH, TN3270, rsh, rexec, etc.
 As an LDAP user
 By using a NFS client supporting the z/OS extensions
 As a CIM user
 As a user of the RMF Distributed Data Server
 As a Communications Server Policy Agent or Network Security Server or Load
Balancing Advisor client
 As a Kerberos principal
In all cases (except for the HTTP server or LDAP server that the administrator may optionally
configure to allow selected access by unauthenticated users as described elsewhere) users
are identified and authenticated by the TOE {IA.1::IA.1.1} before being authorized to
perform any other security relevant action. In the case of jobs submitted by an already-
authenticated user, no additional authentication is required for jobs running with the ID of
the user who submitted them. The internal reader accepts (and relies) in this case on the
authentication performed when the user has logged on to the system {IA.1::IA.1.2}.
An exception to this rule are started tasks, which operate under a protected user ID and are
started either at system startup or through an operator command. Those tasks are not
executing on behalf of a human user and their protected user IDs are exempt from
authentication {IA.1::IA.1.3}. They must only be started from trusted data sets.
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When authenticating a user the TOE allows applications to accept:
 A user ID defined to RACF {IA.1::IA.1.4-R8-RACF-1} and the RACF password
{IA.1::IA.1.4-R8-RACF-2} or password phrase {IA.1::IA.1.4-R10-RACF-4} or a
PassTicket {IA.1::IA.1.4-R8-RACF-3}.
 A valid x.509v3 digital certificate that the application has validated using TLSv1.1-,
TLSv1-, or SSLv3-based client authentication and presented to RACF via initACEE (or
indirectly via __certificate()) or mapped to a RACF user ID R_usermap(), for those
applications supporting TLSv1.1-, TLSv1- or SSLv3-based client authentication (see
Authentication via Client Digital Certificates) . {IA.1::IA.1.4-R13-MULTI-1}
{IA.1::IA.1.4-R13-RACFEAL5-1}
 A valid Kerberos service ticket for the client Kerberos principal, which the
R_usermap() service will convert to a RACF user ID for use by the application, for
those applications supporting Kerberos (see Authentication via Kerberos)
{IA.1::IA.1.4-R13-MULTI-2} {IA.1::IA.1.4-R13-RACFEAL5-2}. The application may also
request entry of a valid RACF user ID and password/phrase {IA.1::IA.1.4-R10-MULTI-
3} and if so the application must run the user’s session under that ID {IA.1::IA.1.4-
R8-MULTI-5}.
 For SSH login functions (ssh, scp, sftp) RACF will also verify the specified
password/phrase {IA.1::IA-1.4-R10-SSH-1}. For clients authenticating using
public/private keys, SSH will verify the private key using information from the RACF
keyring when configured to allow this authentication method {IA.1::IA-1.4-R12-SSH-
2}
 The NFS server must be configured with SECURITY(SAF or SAFEXP) and in this mode
will support authentication of the client via either Kerberos or the mvslogin
command. If the client uses mvslogin and does not use Kerberos, then the NFS
server will validate the user ID and password/phrase using RACF {IA.1::IA.1.4-R12-
NFS-1} . If the client uses Kerberos then the NFS server will use SAF and RACF
functions to map the Kerberos principal to a local RACF user ID and will use that ID
for all NFS security functions {IA.1::IA.1.4-R11-NFS-2}.
 For LDAP authentication:
o With an SDBM DN, the z/OS LDAP server accepts the DN and a RACF
password/phrase, and presents the user ID from the DN, together with the
password/phrase, to RACF for authentication. {IA.1::IA.1.4-R10-LDAP-1}.
o With an LDBM DN, the z/OS LDAP server accepts the DN and a RACF
password/phrase. It transforms the LDAP-style DN into a RACF user ID by
lookup within the LDBM database, and presents the resulting RACF user ID
and the supplied password/phrase to RACF for verification {IA.1::IA.1.4-R10-
LDAP-2}.
o With the ICTX plug-in (for remote authorization or remote auditing extended-
operation requests) the z/OS LDAP server accepts an ICTX-format DN of the
form racfid=userid,cn=ictx and the RACF user’s password/phrase, and the
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plug-in presents the user ID from the DN, together with the password, to RACF
for authentication. {IA.1::IA.1.4-R10-EIM-1}.
o Additionally, LDAP will allow authentication via a digital certificate presented
over an SSL or TLS connection when doing an external SASL bind, and will
map the certificate to a RACF user ID using TOE functions, failing the bind if
RACF does not recognize the certificate. This will work for access to SDBM or
LDBM data {IA.1::IA.1.4-R10-LDAP-3}. For SDBM, LDAP will provide that RACF
user ID when accessing the SDBM back-end {IA.1::IA.1.4-R10-LDAP-4}. For
LDBM, LDAP will transform the RACF user ID into an SDBM-style DN which
(based on administrator-supplied LDAP configuration options) can either
replace or supplement the DN contained in the certificate {IA.1::IA.1.4-R10-
LDAP-5}.
 For authentication to the CIM server, CIM accepts a RACF user ID and password or
PassTicket and uses RACF to validate them before allowing connection {IA.1::IA.1.4-
R8-CIM-1}. Subsequently, if RACF validates the ID and password, the CIM server
continues authentication by ensuring that the user has access to the CIMSERV
resource in the (customer-defined) WBEM RACF class according to the type of
request {IA.1::IA.1.4-R8-CIM-2}. In addition the CIM server uses pthread_security to
process requests that access/manipulate system resources under the requestor’s
user ID {IA.1::IA.1.4-R8-CIM-3}. For use of PassTickets the administrator can
configure CIM to use either the standard z/OS UNIX application ID of OMVSAPPL, or to
use a CIM-specific application ID of CFZAPPL {IA.1::IA.1.4-R10-CIM-4}.
 The RMF Distributed Data Server (DDS) authenticates users via a RACF user ID and
password or PassTicket {IA.1::IA.1.4-R11-RMF-1}.
 The Communications Server Policy Agent Server {IA.1::IA.1.4-R9-CS-POLCEN-1} and
Network Security Server {IA.1::IA.1.4-R9-CS-NSS-1} accept a RACF user ID and
password or PassTicket from their clients during session initiation and use RACF to
validate them before allowing connection.
 The Communications Server Network Security Services (NSS) XMLAppliance discipline
SAFAccess service accepts a RACF user ID and password or PassTicket and validates
them at the request of the XML Appliance client {IA.1::IA.1.4-R10-CS-XMLApp-1}. The
SAFAccess service can also perform an access control check for a specified resource
when requested to do so {AC.4::AC-R10-CS-XMLApp-4}.
 The Communications Server NSS also provides XMLAppliance services to:
o Provide certificate management operations {SM.4::SM-R11-CS-XMLApp-5}
o Provide private key operations to allow retrieval of private keys from RACF
certificates {SM.4::SM-R11-CS-XMLApp-6}, and to perform RSA signature
creation and RSA signature verification using ICSF-protected keys {SM.4::SM-
R11-CS-XMLApp-7}.
 The Communications Server Load Balancing Advisor accepts a client digital certificate
via SSL/ TLS from its clients (Load Balancing Agents, external load balancers) and
uses RACF to validate them before allowing connection {IA.1::IA.1.4-R10-CS-LBA-1}.
Following a successful authentication, the Load Balancing Advisor further restricts
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access by requiring that the user have READ access to SERVAUTH resource EZB.LBA.
[one of: AGENTACCESS, LBACCESS]. <system-name>.<tcp-sysplex-group-name>
{IA.1::IA.1.4-R10-CS-LBA-2}.
Some additional considerations:
 If security label (SECLABEL) processing is active (mandatory in Labeled Security
Mode), the user may also specify the security label he wants to have for the session
or job unless the security label is already restricted by the port of entry. This user-
supplied label must be within the set of labels the user is allowed to use. With this
processing active, if the user does not supply a security label, a defined default
security label is chosen depending on the user’s label and the label of the port of
entry {IA.1::IA.1.5}
 For access to UNIX functions, the user must have a valid UID and his default group
must have a valid GID {IA.1::IA.1.6}. For users without a UID or GID, the FACILITY
class profile BPX.DEFAULT.USER may be used to derive a default UID and GID which
will be used for UNIX access checking {IA.1::IA.1.6-R8-USS-1}. For accountability, any
audit records created by UNIX functions for such a default user will indicate that the
default ID was assigned, and will show both the UID and the RACF user ID
{IA.1::IA.1.6-R8-USS-2}.
 If the user is in additional groups they may have GIDs, too, and if so UNIX access
checking will make use of those additional GIDs {IA.1::IA.1.6-R8-USS-3}.
 If the user ID is in REVOKE status, RACF prevents user from entering the system at all
or entering the system with certain groups {IA.1::IA.1.7}.
 For a user defined as a system administrator (that is, one who has the system
SPECIAL attribute) a message is displayed on the console asking the operator if the
user shall be revoked if he exceeds the number of failed login attempts due to
incorrect passwords {IA.1::IA.1.7-R8-RACF-1} or if he exceeds the system inactivity
interval {IA.1::IA.1.7.R8-RACF-2}.
 For users in the TSO environment the administrator can impose restrictions on
whether the user can use the system on this day and at this time of the day. This is
checked only when using a terminal from a defined set. This does not apply to
operator console login, telnet, rlogin, rsh, rexec, ssh, scp, sftp, LDAP, z/OS Network
Authentication Service, HTTP, ftp, or to batch jobs {IA.1::IA.1.8}.
 RACF also checks if the user is authorized to access the terminal (which can also
include day and time restrictions for accessing that terminal) or other port of entry
{IA.1::IA.1.9}.
 RACF also checks if the user is authorized to use the application (if specified)
{IA.1::IA.1.10}.
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 A user may have SURROGAT authority for another user. This allows him to submit a
job under the user ID of this other user without specifying the password or to use the
z/OS UNIX su command to switch to this user’s ID without specifying the password
{IA.1::IA.1.11}. It also allows appropriately-authorized servers (e.g, HTTP) to switch a
session to run under a pre-specified ID {IA.1::IA.1.11-R8-MULTI-1}. In Labeled
Security Mode, the surrogate user who submits the job must have read access to the
security label under which the job runs {IA.1::IA.1.12}. The job runs with the user ID
that the job card specifies, not the surrogate user’s user ID. The audit record for
surrogate job submission identifies both the surrogate user and the jobcard user ID
{IA.1::IA.1.13}.
8.1.2.2 RACF Passwords and Password Phrases
In RACF, the user selects his own password/phrase and only the user knows the value
chosen. If the user has forgotten his password/phrase and it needs to be reset, the security
administrator will reset the password/phrase {IA.2::IA.2.1-R10}. When the system
administrator follows the rules for the evaluated configuration, this new password/phrase
should be in an expired state, thus forcing the user to enter a new password/phrase on the
next logon {IA.2::IA.2.2-R10}. When creating a new user ID for a pseudo-user that is not a
protected user ID, the initial password/phrase may be marked as nonexpired, allowing it to
be used without being changed first. {IA.2::IA.2.3-R10}.
Password Quality
A system administrator can set a variety of system-global rules for forming valid passwords
using the SETROPTS command (for system-wide settings) or (to a lesser extent) using the
password command to affect only one user. He can change such parameters as the number
of days a password is valid for, how long to maintain password history to prevent the user
from reusing the same password again, the minimum number of days between password
changes, and syntax rules for password content.
When a user changes a password, RACF treats the new, user-supplied password as an
encryption key to transform the RACF user ID into an encoded form using the DES algorithm
that it stores on the database. The password is not stored in clear text {IA.2::IA.2.4}.
The following system-wide options can be set to enforce a minimum strength of passwords
using the PASSWORD option in the SETROPTS command:
 Minimum and maximum length of passwords (LENGTH(m1:m2) as part of a RULE
suboption) {IA.2::IA.2.5}
 Maximum password lifetime (INTERVAL suboption) {IA.2::IA.2.6} and minimum
passwordchange time (MINCHANGE option) {IA.2::IA.2.V1R7-1}
 Number of passwords from the user’s password history that are not allowed for a new
password (HISTORY suboption) {IA.2::IA.2.7}
 Maximum number of consecutive failed authentication attempts until the REVOKE
attribute is set in the user’s profile (REVOKE suboption) {IA.2::IA.2.8}
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 Differentiate between upper- and lowercase characters with the
PASSWORD(MIXEDCASE) option {IA.2::IA.2.V1R7-2}
 Type of character for each character position of a password. Possible types are
{IA.2::IA.2.9}:
o ALPHA
o ALPHANUM (which includes also the special characters $, # and @)
o VOWEL
o NOVOWEL
o CONSONANT
o NUMERIC
o MIXEDCONSONANT
o MIXEDVOWEL
o MIXEDNUM
o NATIONAL
If the value ALPHANUM is defined for more than one position in the password, at least one
alphabetical value and one numeric value are required by RACF.
When the commands are called in a way that allows the TOE to suppress printing, passwords
are not displayed:
 when entered at a TSO terminal as part of the login process {IA.2::IA.2.10}, or
 when entered at a TSO terminal as part of the ADDUSER, ALTUSER, or PASSWORD
commands when the command contains the PASSWORD keyword but no value
{IA.2::IA.2-R10-RACF-21}, or
 when entered into one of the RACF-supplied ISPF panels that allows specification of a
password {IA.2::IA.2-R10-RACF-22}, or
 when entered at a system operator console as part of the operator logon {IA.2::IA.2-
R8-BCP-1}, or
 when the content of a jobcard is displayed as part of a job’s output {IA.2::IA.2.13}.
Note that the TSF can not ensure that passwords entered into programs executing with the
user's privilege are fully protected from being spoofed. The user has to take care about his
password in those cases as explained in the guidance.
Note that,as previously mentioned, for a local Kerberos user, when using RACF as the KDC’s
registry, the user’s RACF password/phrase and Kerberos password are the same.
Password Phrase Quality
Many of the system rules for passwords set by SETROPTS apply to password phrases, too.
However, RACF does not provide support for content syntax rules when using password
phrases.
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When a password phrase is established for a user, RACF treats the new phrase as a
sequence of encryption keys to transform the RACF user ID into an encoded form using the
DES algorithm with chaining, that it then stores on the database. The password phrase is not
stored in clear text {IA.2::IA.2-R10-RACF-1}.
The following system-wide options that can be set to enforce a minimum strength of
passwords using the PASSWORD option in the SETROPTS command also apply to password
phrases:
 Maximum password phrase lifetime (INTERVAL suboption) {IA.2::IA.2-R10-RACF-2}
and minimum password phrase change time (MINCHANGE option) {IA.2::IA.2-R10-
RACF-3}
 Number of password phrases from the user’s password phrase history that are not
allowed for a new password phrase (HISTORY suboption) {IA.2::IA.2-R10-RACF-4}
 Maximum number of consecutive failed authentication attempts using a password or
password phrase until the REVOKE attribute is set in the user’s profile (REVOKE
suboption) {IA.2::IA.2-R10-RACF-5}
Rather than having an administrator specify syntax rules to specify valid password phrase
content, RACF enforces the following set of predefined rules:
 maximum length: 100 characters in the absence of exit ICHPWX11 {IA.2::IA.2-R10-
RACF-6}
Note: The evaluated configuration of the TOE generally does not allow customers to
implement exits to change the system processing. However, RACF supplies a sample
ICHPWX11 exit and a sample REXX exec IRRPHREX that the sample ICHPWX11 will
invoke. The administrator may install the sample ICHPWX11 unmodified, and may
specify tailoring options in IRRPHREX to apply some additional syntax/content rules.
 minimum length:
o 14 characters in the absence of exit ICHPWX11 {IA.2::IA.2-R10-RACF-7}
o 9 characters if exit ICHPWX11 is present and allows the phrase {IA.2::IA.2-
R10-RACF-8}
 The phrase may not contain the user ID, in either sequential uppercase or sequential
lowercase characters {IA.2::IA.2-R10-RACF-9}
 The phrase must contain at least two alphabetic characters (A-Z, a-z) {IA.2::IA.2-R10-
RACF-10}
 The phrase must contain at least two non-alphabetic characters (numeric,
punctuation, special (including blanks)) {IA.2::IA.2-R10-RACF-11}
 The phrase may not contain more than two consecutive identical characters
{IA.2::IA.2-R10-RACF-12}
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If the administrator chooses to install the supplied sample exit ICHPWX11, the sample REXX
exec IRRPHREX may then apply the following additional checks, if selected by the
administrator, and may then accept a shorter phrase or reject a phrase that RACF would
have accepted:
 The administrator can set the minimum allowable phrase length to a value between 9
and 100 inclusive by setting variable Phr_minlen {IA.2::IA.2-R10-RACF-26}
 The administrator can set the maximum allowable phrase length to a value between
9 and 100 inclusive by setting variable Phr_maxlen {IA.2::IA.2-R10-RACF-13}
 The administrator can set a more restrictive set of characters for password phrases
by setting the variables numbers, letters, special, and Phr_allowed_chars {IA.2::IA.2-
R10-RACF-14}
 The administrator can prevent leading or trailing blanks in password phrases by
setting the variables Phr_leading_blanks or Phr_trailing_blanks to “no” IA.2::IA.2-R10-
RACF-15}
 The administrator can prevent use of password phrases that contain a case-
insensitive character string from the user's name by setting the variable
Phr_name_allowed to “no” and setting the variable Phr_name_minlen to the longest
substring allowed {IA.2::IA.2-R10-RACF-16} Example: if the user's name is John Smith
the administrator could prevent the user from specifying a phrase containing John or
john or jOhn or Smit by appropriate settings of the variables.
 The administrator can enable a triviality check by setting the variable Phr_triviality to
“yes”. This will prevent use of a new password phrase that differs from the old one
only insertion/deletion of spaces or changing character case. It also will reject a new
phrase when the shorter of the old and new phrases is simply a substring of the
other. {IA.2::IA.2-R10-RACF-17}
 The administrator can prevent use of new phrases that do not differ in a significant
number of characters from the old phrase by setting the variable Phr_min_unique to
the number of positions that must differ. In addition, if the variable
Phr_min_unique_norm has the value “yes” the exec will first normalize the old and
new phrases to be checked by converting them to uppercase and removing spaces.
{IA.2::IA.2-R10-RACF-18}
 The administrator can prevent the user of a new phrase which simply reorders the
words of the old phrase by setting the variables Phr_unique_words (number of words
that must be unique), Phr_word_minlen (minimum length of the unique words), and
Phr_word_unique_upper (if “yes” then the exec will convert the old and new phrases
to uppercase for this check {IA.2::IA.2-R10-RACF-19}
 The administrator can provide a list of disallowed words by setting the variables
Phr_dict.0 to the number of words in a supplied list, and supplying the list in variables
Phr_dict.1, Phr_dict.2, etc. {IA.2::IA.2-R10-RACF-20}
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When the commands are called in a way that allows the TOE to suppress printing, the
phrase is not displayed:
 when entered at a TSO terminal as part of the login process {IA.2::IA.2-R10-TSO-23},
or
 when entered into one of the RACF-supplied ISPF panels that allows specification of a
password phrase {IA.2::IA.2-R10-RACF-25}.
Note that the TSF can not ensure that password phrases entered into programs executing
with the user's privilege are fully protected from being spoofed. The user has to take care
about his password phrase in those cases as explained in the guidance.
8.1.2.3 RACF PassTickets
PassTickets provide a one-time {IA.2::IA.2.14-R8-RACF-1} (by default, though administrators
can change that for selected applications {IA.2::IA.2.14-R8-RACF-2}), cryptographically-
computed, password substitute that may be used to authenticate a user {IA.2::IA.2.14-R8-
RACF-3}. The computed value comprises information about the user ID, the application to
which the user is authenticating, and the date and time-of-day {IA.2::IA.2.14-R8-RACF-4}. A
given PassTicket is usable only within a time interval of plus-or-minus 10 minutes from the
time of generation {IA.2::IA.2.14-R8-RACF-5}.
The cryptographic computation of a PassTicket requires usage of a secret key assigned by
the administrator, and (for computations on z/OS) maintained within a profile in the
PTKTDATA class. PassTicket evaluation also uses PTKTDATA profiles to determine the
appropriate secret key to use.
For PassTicket generation, RACF locates a PTKTDATA profile whose name matches the
application name, and extracts the secret key from it. The generation of the PassTicket then
proceeds, using the user ID, application name, time/date, and selected key as inputs to the
generation algorithm.
For PassTicket evaluation, RACF receives a user ID, application name, and optionally a group
name, and locates a PTKTDATA profile to determine the secret key using a series of profile
lookups, until a matching profile is found:
i. application-name.group-name.user-ID {IA.2::IA.2.14-R8-RACF-6}
ii. application-name.user-ID {IA.2::IA.2.14-R8-RACF-7}
iii. application-name.group-name {IA.2::IA.2.14-R8-RACF-8}
iv. application-name {IA.2::IA.2.14-R8-RACF-9}
z/OS UNIX uses, by default, an application name (APPLID) of OMVSAPPL {IA.2::IA.2.14-R10-
USS-1} when authenticating users via:
 The __login(), or pthread_security_np() services.
 The _passwd() service if issued from a thread created by pthread_create() which
subsequently issued pthread_security_np(), and if the _passwd() call does not specify
a new password.
The application may override this default in one of these ways:
 For pthread_security_np() and __passwd(), the application can
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 update the BPXYTHLI control block to indicate that z/OS UNIX should instead
use the job name as the APPLID value {IA.2::IA.2.14-R10-USS-2}, or
 update the BPXYTHLI control block to indicate a specific APPLID to use
{IA.2::IA.2.14-R10-USS-3}.
 By changing to use one of the corresponding new services
pthread_security_applid_np(), __login_applid(), and __passwd_applid() the application
can specify an APPLID value directly as a parameter on the call {IA.2::IA.2.14-R10-
USS-4}.
RACF provides two services for generation of PassTickets:
i. An internal service usable only by key 0 callers and located via the RCVT
(RCVTPTGN); {IA.2::IA.2.14-R8-RACF-10}
ii. An external service usable by appropriately authorized users or servers, and invoked
by R_ticketserv() or R_gensec() {IA.2::IA.2.14-R8-RACF-11}. To use one of these
services for PassTicket generation the caller needs UPDATE authority to resource
IRRPTAUTH.application-name.target-user-ID in the PTKTDATA class. {IA.2::IA.2.14-R8-
RACF-12}
RACF also allows applications to evaluate PassTickets by using the R_ticketserv() or
R_gensec() services {IA.2::IA.2.14-R8-RACF-13}. Use of these services for PassTicket
evaluation requires READ authority to IRRPTAUTH.application-name.target-user-id in the
PTKTDATA class {IA.2::IA.2.14-R8-RACF-13a}.
z/OS also allows Java applications running on z/OS to generate or evaluate PassTickets,
using a JNI interface to R_ticketserv() and R_gensec() {IA.2::IA.2.14-R8-RACF-14}.
The Communications Server uses PassTickets as part of its participation in the Express
Logon Facility (ELF) and Web Express Logon (WEL) single signon solutions.
 Express Logon Facility (ELF) --This function is provided in a Two-Tier or Three-Tier
model for single-signon to a z/OS application. With either model, a user presents an
X.509v3 digital certificate to the z/OS ELF service, which in the two-tier model is a
TN3270 server and in the three-tier model is a Digital Certificate Access Server
(DCAS). When the TN3270 server or DCAS receives the certificate and a target
application name, it will invoke RACF to : 1) map the certificate to a RACF user ID 2)
Generate a PassTicket for the user ID and target application. {IA.2::IA.2.14-R9-ELF-1}
In the two-tier model DCAS is not involved and the TN3270 server runs on z/OS. Here,
the ELF function is agreed upon by the TN3270 sever and client. When the TN3270
server receives the logon panel (by examining the input data), it will invoke the RACF
services to map the certificate to a user ID and generate a PassTicket, which it will
then insert the user ID and PassTicket into the logon panel, subsequently passing the
panel to the target application for logon. (IA.2.61) {IA.2.14-R9-ELF-2} In the case of
the three-tier model, the TN3270 server does not run on z/OS, but runs on a
distributed platform. In this case, the distributed TN3270 server (upon receipt of the
logon panel), invokes DCAS, passing it the certificate and target application name (on
behalf of the end user). DCAS then invokes RACF to map the certificate to a User ID
and generate a PassTicket. DCAS passes this information back to the TN3270 server
which inserts the User ID and PassTicket into the logon panel, and subsequently
passes the panel to the target application for logon. {IA.2::IA.2.14-R9-ELF-3}
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 Web Express Logon (WEL) --In this model (non certificate-based), a DCAS client is
requesting a PassTicket on behalf of an end user. Note that as part of the single-
signon architecture, that end user has already been authenticated at some point
prior to the DCAS client requesting the PassTicket. In this case, the DCAS server
supports two types of requests:
i. It can receive a valid z/OS user ID from the client and the target application
name. It will pass these to RACF requesting a PassTicket for that user ID and
application. {IA.2::IA.2.14-R9-WEL-1}
ii. It can receive a principal name from the client along with the target
application name. It will pass these to RACF requesting a z/OS user ID that has
been mapped to the principal name and a PassTicket which will be returned to
the requesting client. In this case, it is required that the z/OS user ID be
mapped to a principal name using the RACF KERBLINK class. {IA.2::IA.2.14-R9-
WEL-2}
 Additional details:
o For ELF, in the two-tier model, communication between the TN3270 client and
server requires SSL with client authentication at a minimum. {IA.2::IA.2.14-
R9-ELF-4}
o For ELF, in the three-tier model, communication between the distributed
TN3270 server and DCAS requires SSL with client authentication at a
minimum. The SSL and DCAS client in this case is the TN3270 server itself. In
the evaluated configuration the DCAS server will also verify that that its client
(the TN3270 server) is authorized to SERVAUTH resource EZA.DCAS.system-
name. {IA.2::IA.2.14-R9-ELF-5}
o For WEL, communication between the DCAS server and client (WEL server)
requires SSL with client (WEL server) authentication at a minimum. In the
evaluated configuration the DCAS server will also verify that its client (the
WEL server) is authorized to SERVAUTH resource EZA.DCAS.system-name.
{IA.2::IA.2.14-R9-WEL-3}
Additionally, the Communications Server provides the DCAS server (Digital Certificate
Application Server) which can be used by applications running in the network, perhaps as
part of a single-signon service. DCAS provides two functions:
i. Generate a PassTicket for an application-specified user ID and application name;
{IA.2::IA.2.14-R8-DCAS-1}
ii. Map an application-specified digital certificate for the server’s client to a RACF user
ID, and generate a PassTicket for that user and an application-specified application
name. {IA.2::IA.2.14-R8-DCAS-2}In order to use DCAS, the network-based application
must connect to DCAS using an SSL session with client authentication, and provide
its own digital certificate that maps to a RACF user ID {IA.2::IA.2.14-R8-DCAS-3}. In
the evaluated configuration that mapped user ID must be authorized to resource
EZA.DCAS.system-name in the SERVAUTH class {IA.2::IA.2.14-R8-DCAS-4}.
The Communications Server's Network Security Services Server provides a SAFAccess
service as part of its XMLAppliance discipline. The SAFAccess performs RACF userid
authentication on behalf of the XMLAppliance client and supports passwords and PassTickets
as authentication tokens. NSS clients must connect to the NSS server using a TLS-protected
session and must also authenticate themselves to the server using their own RACF userid
and password or PassTicket {IA.2::IA.2.14-R10-CS-XMLApp-2}.
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PassTickets are also used internally by the Kerberos KDC server as part of the processing
when users change their Kerberos passwords.
8.1.2.4 Authentication via Client Digital Certificates
In the evaluated configuration, SSL- or TLS-aware applications, or the Application-
Transparent TLS (AT-TLS) functions of the Communications Server, can accept client
certificates and map them to RACF user IDs as part of the client authentication process.
Such applications must be configured to use RACF to store the keyrings that contain the
application private key and the allowed Certificate Authority (CA) certificates that may be
used to provide the client certificates that the application will support. The security
administrator will use RACDCERT to establish those keyrings, which may reside in RACF
profiles in the DIGTRING class or in PKCS#11 tokens maintained in ICSF, and thus to approve
of any CAs that will be used. Any CA used in the evaluated configuration must support
Certificate Revocation Lists (CRLs) maintained in an LDAP registry, and the security
administrator must configure the application to use the CRLs. This configuration may be
application-specific, or may be done by establishing LE environment variables that System
SSL will use in the absence of specific application-provided CRL configuration information.
The first step in the client authentication process is for the server or AT-TLS to acquire the
client certificate via the standard SSLv3 or TLS data flows. As part of that processing,
System SSL will validate the client certificate using the gsk_validate_certificate_mode()
function, passing the validation mode to be applied to the validation processing.
System SSL can validate certificates using either the processing specified by [RFC2459], or
by [RFC3280], under control of an environment variable or specifications provided by the
application. In the absence of an environment variable or application-provided specification,
System SSL will first validate using [RFC2459] and if that fails will then retry using
[RFC3280] {IA.2::IA.2.15-R11-SSL-20}.
gsk_validate_certificate_mode will perform the following checks against the client certificate
and certification chain:
i. The certificate's subject name must be identified by either a non-empty distinguished
name (with an optional SubjectAltname certificate extension) or an empty
distinguished name with a SubjectAltName certificate extension: RFC2459:
{IA.2::IA.2.15-R8-SSL-1}.
RFC3280: {IA.2::IA.2.15-R11-SSL-15} SubjectAltName Extension must be critical.
ii. Certificate Authority certificates must have a non-empty subject name {IA.2::IA.2.15-
R8-SSL-2}.
iii. The certificate issuer name must not be an empty distinguished name {IA.2::IA.2.15-
R8-SSL-3}.
iv. The CertificatePolicies extension, if present, must not be marked critical (RFC2459)
{IA.2::IA.2.15-R8-SSL-4}. For RFC3280, if the certificate policies extension is present,
it must be marked critical and must satisfy the policies defined by the issuing
certificate chain. {IA.2::IA.2.15-R11-SSL-16}
v. The current time must not be earlier than the start of the certificate validity period
{IA.2::IA.2.15-R8-SSL-5}.
vi. The issuer's certificate must be a valid CA certificate, and the root certificate and any
intermediate signing certificates not in the client’s message must be present in the
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server’s key ring {IA.2::IA.2.15-R8-SSL-7}. The server's certificate store can either be
a RACF key ring (DIGTCERT class) or a PKCS#11 token in ICSF TKDS (CRYPTOZ class)
{IA.2::IA.2.15-R9-SSL-14}.
vii. The certificate signature must be correct and using a supported signature (RSA 1024-
4096 bit key with hashing algorithm --MD5, SHA-1, SHA-224, SHA-256, SHA-384 or
SHA-512 or DSA 1024-bit key with hashing algorithm SHA-1) {IA.2::IA.2.15-R10-SSL-
8}
or ECDSA 160-521 bit keys with hashing algorithm SHA-1, SHA-224, SHA-256, SHA-
384, SHA-512) {IA.2::IA.2.15-R12-SSL-21}
viii.No certificate in the certification chain can be revoked or expired {IA.2::IA.2.15-R8-
SSL-10}.
ix. For CA certificates, the BasicConstraints extension, if present, must have the CA
indicator set and the path length constraint must not be violated by subordinate
certificates in the certification chain RFC2459 – {IA.2::IA.2.15-R8-SSL-11}
RFC3280 -- {IA.2::IA.2.15-R11-SSL-17} --Basic Constraints extension must be
present.
x. If the issuing certificate chain has defined any name constraints through Name
Constraints extensions, the constraints must not be violated by the subject certificate
{IA.2::IA.2.15-R8-SSL-12}.
xi. The key usage extension, if present in a CA certificate, must specify signing
capability RFC2459 – {IA.2::IA.2.15-R8-SSL-13}
RFC3280 -- {IA.2::IA.2.15-R11-SSL-18} --Key Usage extension must be present.
xii. Certificate Authority certificates with a Key Usage extension present which has the
keyCertSign bit set must have a Basic Constraints extension present which has the
CA indicator set. RFC3280 -- {IA.2::IA.2.15-R11-SSL-19}
After System SSL has validated the client certificate, the application (or AT-TLS) can map it
to a RACF user ID via the R_usermap() callable service {IA.2::IA.2.16-R8-RACF-1}. Or the
application can directly create a security environment for the user by using the
pthread_security_np() service {IA.2::IA.2.16-R8-USS-1}, the InitACEE() service {IA.2::IA.2.16-
R8-RACF-3}, or the _certificate() service {IA.2::IA.2-16-R9-USS-1} which will accept the
certificate as input. In either case, RACF will:
i. Examine the RACF database and determine whether the certificate is installed and
registered to a specific user. If so, return that user ID {IA.2::IA.2.17-R8-RACF-1}
ii. Otherwise, try to find the best-matching mapping profile (DIGTNMAP class), and
return the user ID specified in the profile’s APPLDATA field:
a. Check for a filter of subject’s-full-name.issuer’s-full-name {IA.2::IA.2.17-R8-
RACF-2}
b. Iteratively remove nodes from the subject’s name and check for a filter of the
form: subject’s-partial-name.issuer’s-full-name {IA.2::IA.2.17-R8-RACF-3}
c. Check for a filter of the form: subject’s-full-name {IA.2::IA.2.17-R8-RACF-4}
d. Iteratively remove nodes from the subject’s name and check for a filter of the
form: subject’s-partial-name {IA.2::IA.2.17-R8-RACF-5}
e. Check for a filter of the form: issuer’s-full-name {IA.2::IA.2.17-R8-RACF-6}
f. Iteratively remove nodes from the issuer’s name and check for a filter of the
form: issuer’s-partial-name {IA.2::IA.2.17-R8-RACF-7}
iii. Otherwise, try to find the best-matching mapping profile (DIGTNMAP, DIGTCRIT class)
that matches the mapping criteria specified by the application that presented the
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certificate to RACF, and if found return the user ID specified in the DIGTNMAP
profile’s APPLDATA field {IA.2::IA.2.17-R8-RACF-8}.
iv. Otherwise, if the certificate contains at least one hostIDMappings extension with a
host-name and user ID {IA.2::IA.2.17-R8-RACF-9} and the certificate was issued by a
CA defined to RACF as having the HIGHTRUST status {IA.2::IA.2.17-R8-RACF-10},
then RACF will examine each of the hostIDMappings extensions, in order
{IA.2::IA.2.17-R8-RACF-11}. RACF will determine whether the application has READ
access to IRR.HOST.host-name in the SERVAUTH class, and if so RACF will return the
user ID associated with that host-name {IA.2::IA.2.17-R8-RACF-12}.
8.1.2.5 Authentication via Public/Private Key (SSH)
OpenSSH supports authentication via public/private keys, however for the evaluated
configuration OpenSSH on z/OS must be configured to obtain those public/private key pairs
from digital certificates associated with RACF key rings. The existing RACDCERT command
can be used to generate the keys and a certificate, or the certificates may be generated
elsewhere and imported into RACF using RACDCERT. Public/private keys stored directly in
the UNIX file system must not be used.
When a remote user authenticates to the OpenSSH server, the server will use the public key,
obtained via a digital certificate which is associated with the user's configured key ring, to
perform the authentication. {IA.2::IA.2-R12-SSH-KEY-1}
When a z/OS user acts as an SSH client, connecting to an SSH server, the client will obtain
the necessary private key via a digital certificate which is associated with the user's
configured key ring to perform the authentication. {IA.2::IA.2-R12-SSH-KEY-2}
The private key is not needed at the server when a client authenticates. The public keys
must be distributed to remote hosts. When stored in a key ring, the certificate must be
exported (via RACDCERT) and manually copied (e.g. via FTP) to the remote host, where it
will be imported into that system's key ring.
When configured to use key rings, the OpenSSH server and client code will use existing
System SSL interfaces to pull the keys from the RACF key ring, and the server and client will
need authority to those key rings to use the RDATALIB service. {IA.2::IA.2-R12-SSH-KEY-3}
8.1.2.6 Authentication via Kerberos
In the evaluated configuration Kerberos-aware applications can accept Kerberos service
tickets from Kerberos clients (principals), map them to RACF user IDs, and allow them to
access the system using their RACF identities. In addition, users running on z/OS may have
Kerberos identities, and act as clients (Kerberos principals) to Kerberos-aware servers.
For authentication via Kerberos:
i. The client (principal) will obtain a Ticket Granting Ticket (TGT) by authenticating to
the assigned Kerberos registry, which may be a z/OS Network Authentication Service
instance KDC {IA.2::IA.1.4-R8-KERB-1} or some non-z/OS KDC. This initial
authentication will follow standard Kerberos protocols, using one of the encryption
protocols specified for the KDC {IA.2::IA.1.4-R8-KERB-2}. If the z/OS Network
Authentication Service KDC is used for initial principal authentication, the z/OS
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Network Authentication Service will map the Kerberos principal name to a RACF user
ID and the password used to derive the key info for the Kerberos authentication
exchanges will be the user’s RACF password or phrase, whichever was last
established for the user {IA.2::IA.1.4-R10-KERB-3}.
ii. As is standard with the Kerberos protocol, the client will then acquire a service ticket
for the desired server, and will present that ticket to the server for validation and
mapping to a RACF identity.
iii. The z/OS Network Authentication Service will validate the addresses in the service
ticket, as required by RFC4120, if the administrator has requested the validation by
specifying CHECKADDRS(YES) on the RDEFINE/RALTER for the KERB segment in the
KERBDFLT profile in the REALM class. {IA.2::IA.1.4-R13-KERB-9}
iv. {IA.2::IA.1.4-R12-KERB-8} If the service principal in a request is different from the
principal specified on the krb5_rd_req, krb5_rd_req_verify, or gss_accept_sec_context
API call, but the request is otherwise valid, the request will still be approved if and
only if all the following are true:
• use_dvipa_override=1 is specified in the libdefaults section of the
krb5.confconfiguration file,
• both principals are in the standard “Primary/Instance@Realm”format (with
only one instance),
• both the primary and the realm in the request are the same as those
provided in the API call, and
• the KRB5_SERVER_KEYTAB environmental variable is set to 2 and the
application server that invoked the API call has at least READ access in the
KERBLINK class to the principal specified in the request
-OR-
an entry in the keytab file matches the service principal name, version
number, and encryption type from the incoming service ticket.
v. If the user is assigned to a foreign Kerberos realm (with respect to the TOE server
application), the user will first use kinit to acquire a TGT from his local KDC. If a peer
trust relationship is defined between the two KDCs, the client application can use this
initial TGT to obtain a TGT for the remote z/OS KDC from its local KDC, which is then
used by the client application to obtain a service ticket from the remote z/OS
KDC. The z/OS KDC will only issue a service ticket for a TGT produced by a KDC in
another realm if the administrator for each realm has configured a trust relationship
between the two KDCs {IA.2::IA.1.4-R8-KERB-4}. This trust relationship may be
transitive and involve the client contacting a series of KDCs before finally obtaining
the TGT for the remote z/OS KDC {IA.2::IA.1.4-R8-KERB-5}.
iv. If the application server is running on z/OS, once it has validated the client principal’s
service ticket, it uses the R_usermap() service to determine the local RACF user ID
associated with the Kerberos principal that may be defined to the z/OS Network
Authentication Service {IA.2::IA.1.4-R8-KERB-6} or foreign {IA.2::IA.1.4-R8-KERB-7}
principal that is defined to another Kerberos realm with an established trust
relationship with the z/OS Network Authentication Service.
8.1.2.7 Started procedures
With the concept of a started procedure, the TOE provides a mechanism where a defined
task can be started by an operator, but then operates under a defined user ID that is
specifically assigned to the started procedure itself {IA.3::IA.3.1}.
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A started procedure consists of a set of job control language statements that are frequently
used together to achieve a certain result. Started procedures usually reside in the system
procedure library, SYS1.PROCLIB, which is a partitioned data set. A started procedure is
usually started by an operator, but can be associated with a functional subsystem. For
example, SMS is treated as a started procedure even though it does not need to be
specifically started with a START command.
Only RACF-defined users and groups can be specifically authorized to access RACF-protected
resources {IA.3::IA.3.2}. Other users can access those resources with the authority allowed
in the UACC entry of the RACF profile controlling access to the resource. However, started
procedures have system-generated JOB statements that do not contain the USER, GROUP, or
PASSWORD parameter.
To enable started procedures to access RACF-protected resources with other authorities
than those defined in the UACC entry of the profile protecting the resource, started
procedures must have RACF user IDs and group names {IA.3::IA.3.4}. By assigning them
RACF identities, an installation can give started procedures specific authorization to access
RACF-protected resources. For example, one can allow JES to access spool data sets.
To associate the names of started procedures with specific RACF group names and user IDs,
an administrator can do one of the following:
 Set up the STARTED class (the recommended method)
 Create a started procedures table (ICHRIN03)
Assigning RACF user IDs to started procedures
As with any other user ID and group name, the user ID and group name that is assigned to a
started procedure must be defined to RACF using the ADDUSER and ADDGROUP commands,
and the user must be connected to the group. The administrator also needs to use the
PERMIT command to authorize the users or groups to get access to the required resources.
Protected user IDs
The user IDs that an administrator assigns to started procedures should have the
PROTECTED attribute unless the started procedure is required to have a user ID with a
password defined. Protected user IDs are user IDs that have both the NOPASSWORD and
NOOIDCARD attributes {IA.3::IA.3.5}. They are defined or modified using the ADDUSER and
ALTUSER commands. Protected user IDs can not be authenticated via a password, password
phrase, or RACF PassTicket, and are protected from being revoked through incorrect
password attempts {IA.3::IA.3.6-R12-RACFEAL5}.
8.1.2.8 Authentication by trusted servers
Trusted servers of z/OS may be required to perform user authentication. They all use RACF
to verify the credentials presented by a user for authentication. Those trusted servers may
have some special configuration options that are explained in this section.
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Handling of user authentication in the HTTP server
Users may connect to the HTTP server of the TOE. The server will assign an installation-
defined pseudo-user ID to a user unless the user is authenticated with his user ID and
password {IA.3::IA.3.V1R7.1}. Access checks to protected resources the HTTP server
accesses on behalf of an unauthenticated user will be performed using the access rights of
this installation-defined pseudo user ID {IA.3::IA.3.V1R7.2}.
The HTTP server also provides a function to identify and authenticate users using their user
ID and password when the PROTECT directive specifies UserID %%CLIENT%%
{IA.3::IA.3.V1R7.3}. Once authenticated successfully, the access rights of the authenticated
user are checked when the HTTP server attempts to access resources protected by that
PROTECT directive {IA.3::IA.3.V1R7.4}. The HTTP server uses RACF for user identification
and authentication {IA.3::IA.3.V1R7.5}. Once the user has been successfully authenticated
the HTTP server, when acting on behalf of the user, switches to the MVS user ID of the
authenticated user and all access checks to protected resources are performed by RACF
checking the access rights of this user {IA.3::IA.3.V1R7.6}.
The HTTP Server also supports client authentication via SSL/TLS client authentication using
digital certificates. {IA.3::IA.3-R8-HTTP-1}. To enable this support, the administrator would
specify UserID %%CERTIF%% on the PROTECT directive {IA.3::IA.3-R8-HTTP-2}. The HTTP
server will present the certificate to RACF to map into a RACF user ID {IA.3::IA.3-R8-HTTP-3}
and then proceed with access checking using that RACF identity as above for UserID %
%CLIENT%% {IA.3::IA.3-R8-HTTP-4}.
Handling of user authentication in the FTP server
Users may connect to the FTP server and authenticate with a user ID and password or a
Kerberos service ticket, or a digital certificate as previously described. The FTP server also
supports unauthenticated, or anonymous, access to data. Administrators who have certain
data that they want to serve to unauthenticated users via FTP may enable this anonymous
access. Data access will then occur under a RACF ID that the administrator has specified in
the FTP server configuration file, and only data accessible to that user will be served to the
FTP client. Additionally, as this is intended to be “public” data with unrestricted access, no
audit logs showing the actual human user who accessed the data can be maintained, but the
administrator will have accepted the loss of auditing by configuring anonymous access.
In the evaluated configuration, if the administrator wishes to allow anonymous FTP access,
the following parameters must be specified:
i. ANONYMOUSLEVEL 3
ii. ANONYMOUS user-id/SURROGAT (Note: the administrator can choose any user-id he
wants, but the user must have the RESTRICTED attribute, and an OMVS segment with
a unique UID, a default group with a unique GID, a home directory to which the user
has access, and should have no other group connections.).
iii. ANONYMOUSFILEACCESS HFS or MVS or BOTH
iv. ANONYMOUSFILETYPEJES FALSE
v. ANONYMOUSFILETYPESQL FALSE
With these settings:
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 When the user specifies USER ANONYMOUS the FTP server will prompt for an email
address {IA.3::IA.3-R9-FTP-1}.
 The FTP server will then establish a security environment for the chosen user ID from
the ANONYMOUS statement {IA.3::IA.3-R9-FTP-2}.
 The FTP server’s ID must have SURROGAT authority to BPX.SRV.user-ID {IA.3::IA.3-
R9-FTP-3}.
 The user ID must have an OMVS UID and its default group must have a GID
{IA.3::IA.3-R9-FTP-4}.
 If starting in the UNIX file system or if the user issues a “cd” to switch to the UNIX file
system, the FTP server will issue chroot() to restrict the user to his home directory as
specified in the user’s OMVS segment {IA.3::IA.3-R9-FTP-5}.
 The user will only be able to access data in that home directory {IA.3::IA.3-R9-FTP-6},
or if the user switches to the MVS file system (assuming the administrator specified
ANONYMOUSFILEACCESS MVS or BOTH) the user will have access to only that data to
which the user ID or his group(s) are explicitly permitted {IA.3::IA.3-R9-FTP-7}. No
access to other MVS data via UACC or ID(*) or GLOBAL will be permitted {IA.3::IA.3-
R9-FTP-8}.
The user will not be able to specify SITE FILETYPE JES nor SITE FILETYPE SQL (IA.3.24) (IA.3-
R9-FTP-9)
If desired, the administrator can configure the FTP server to verify an authenticated user's
authority to access the server via a SERVAUTH resource check before allowing access to
data. To do this, the administrator would specify VERIFYUSER TRUE in the FTP configuration
parameters and define a RACF SERVAUTH profile to protect the resource EZB.FTP.<system-
name>.<ftp-daemon-name>.PORT<nnnn> where nnnn represents the port number
assigned to that FTP daemon. The user will need READ access to that resource if it is
protected by a SERVAUTH profile {IA.3::IA.3-R10-FTP-9}.
The administrator may also prevent the user from accessing data in the UNIX file system
(thus restricting the user to accessing traditional MVS data sets). To do this, the
administrator would define a profile in the SERVAUTH class to protect the resource
EZB.FTP.<system-name>.<ftp-daemon-name>.ACCESS.HFS and deny the user access to
the resource via the profile UACC or access list {IA.3::IA.3-R10-FTP-10}.
Handling of user authentication in the CIM server
Users may connect to the CIM server and authenticate with a RACF user ID and password or
with a RACF user ID and PassTicket {IA.3::IA.3-R10-CIM-1}. The CIM server first uses RACF
services to validate the user ID and password or PassTicket. In addition for all user requests
that are to obtain or manipulate system management data, the CIM server dispatches the
request to an extra thread, for which the effective userid is switched to that of the requestor
using the pthread_security_np() service . This way the access to system resources occurs on
behalf of the user's identity rather than under the identity of the CIM server {AC.1::AC.1-
R10-CIM-2}.
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Depending on the type of request the CIM server then ensures that the user has the proper
level of access to the CIMSERV resource in the (customer defined) WBEM RACF class. For
read access to the system data exposed by the CIM server the user requires READ access,
for manipulation of system resources the user requires UPDATE access and for performing
administrative tasks against the CIM server itself the user requires CONTROL access to the
CIMSERV RACF resource {AC.1::AC.1-R10-CIM-3}.
Handling of user authentication in the LDAP server
LDAP user authentication in the evaluated configuration will occur via digital certificates
over SSL/TLS (LDAP SASL bind with EXTERNAL verification) or via an LDAP DN and a RACF
password/phrase.
For users initiating a bind operation with a DN and a password/phrase, the processing that
occurs will depend on the style of DN presented: LDBM, SDBM, or ICTX:
 If the user presents an SDBM-style DN (such as racfid=ID1,profiletype=user,SDBM-
suffix) then LDAP will extract the racfid value. Note that the SDBM-suffix is configured
by the administrator. LDAP will pass that user ID and password/phrase to RACF for
authentication {IA.3::IA.3-LDAP-1}.
 Similar processing happens when users present an ICTX-style DN. Again, LDAP
recognizes this based on a configured suffix value, and invokes the the ICTX plug-in,
which will pass the RACF user ID from the DN and the password to RACF for
authentication {IA.3::IA.3-R9-EIM-1}.
 For LDBM users, the “native authentication” functions of the server are required for
any authenticated access to LDBM in the evaluated configuration. For each LDBM
user, the LDAP administrator will define the user’s distinguished name (DN) in the
LDBM database, together with the RACF user ID that corresponds to that DN. The
LDAP LDBM user will provide his LDAP DN and the RACF password for the user ID
specified by the administrator. LDAP will find the user-specified DN, then call RACF
passing the administrator-specified user ID and the user-specified password
{IA.3::IA.3-R8-LDAP-2}. Note that the evaluated configuration allows the
administrator to configure selected LDBM data for access by users who have not
authenticated, if the administrator decides that such access meets the security
policies in effect for that data
For a SASL bind with a digital certificate (possible only for SDBM or LDBM in this evaluation),
the evaluated configuration requires the administrator to configure LDAP to map the
certificate to a RACF user ID. The administrator must specify the configuration option
sslMapCertificate with a first operand of CHECK, ADD, or REPLACE and a second operand of
FAIL. With this configuration in effect:
 If no RACF user ID is associated with the certificate, LDAP will fail the bind operation
{IA.3::IA.3-R10-LDAP-2}.
 The mapped RACF user ID will be used for any access to the SDBM back-end
{IA.3::IA.3-R10-LDAP-3}.
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 For LDBM operations:
o With ADD specified, LDAP will convert the mapped RACF user ID into an SDBM
DN, and will add that DN to the DN from the certificate, using both DNs for
group gathering and access decisions {IA.3::IA.3-R10-LDAP-4}.
o With REPLACE specified, LDAP will convert the mapped RACF user ID into an
SDBM DN, and will use only that DN for group gathering and access decisions
{IA.3::IA.3-R10-LDAP-5}.
8.1.2.9 Authentication Method Summary
The following TOE applications support client authentication via Kerberos in the evaluated
configuration:
 FTP {IA.3::IA.3-R8-FTP-AUTHKERB}
 ORSH {IA.3::IA.3-R8-RSH-AUTHKERB}
 OTELNET {IA.3::IA.3-R8-TELNET-AUTHKERB}
 NFS {IA.3::IA.3-R8-NFS-AUTHKERB}
The following TOE applications support client authentication via digital certificates when
using SSL/TLS sessions in the evaluated configuration:
 TN3270, when using a TN3270 emulator that supports the Express Logon Facility
(ELF) {IA.3::IA.3-R8-TN3270-AUTHSSL}
 FTP {IA.3::IA.3-R9-FTP-AUTHSSL}
 HTTP Server {IA.3::IA.3-R8-HTTP-AUTHSSL}
 LDAP Server, for SDBM or LDBM access {IA.3::IA.3-R10-LDAP-AUTHSSL}
The following TOE functions support authentication using passwords/phrases in the
evaluated configuration:
 TSO/E {IA.3::IA.3-R10-TSO-AUTHPHRASE}
 NFS {IA.3::IA.3-R12-NFS-AUTHPHRASE}
 OpenSSH {IA.3::IA.3-R10-SSH-AUTHPHRASE}
 The z/OS UNIX shell commands su and passwd {IA.3::IA.3-R10-USS-AUTHPHRASE-1}
 The z/OS UNIX rlogin command {IA.3::IA.3-R10-USS-AUTHPHRASE-2}
 The C runtime functions __login(), __passwd(), pthread_security_np() (and the
variants that accept an APPL ID), and getpass() {IA.3::IA.3-R10-LE-AUTHPHRASE}
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 LDAP Server for SDBM or LDBM (via native authentication) access {IA.3::IA.3-R10-
LDAP-AUTHPHRASE-1}
 FTP Server {IA.3::IA.3-R13-FTP-AUTHPHRASE}
 TN3270 Server {IA.3::IA.3-R13-TN3270-AUTHPHRASE}
OpenSSH supports authentication via public/private key pairs stored in digital certificates
when it is configured to store the certificates in RACF key rings {IA.3::IA.3-R12-SSH-
AUTHRINGS}.
8.1.2.10 Handling of Groups During Authentication
During authentication, RACF and LDAP construct security information that represents the
user (subject) for subsequent use during access checking.
 During RACF authentication, RACF determines whether list-of-groups processing is in
effect or not. If list-of-groups is not in effect, RACF puts the user's default group into
the subject's ACEE, or the group specified by the caller of the RACF interfaces for
user authentication. If list-of-groups is in effect, RACF gathers a list of all the groups
to which the user is connected, and makes a copy of that list in the subject's ACEE.
During access checking (DAC) for MVS resources, RACF can then base its decisions
on both the user ID and on the group membership of the user {IA.3::IA.1.14-R12-
RACFEAL5-1}.
 When a user attempts to use UNIX functions, RACF selects from the group(s) in the
subject's ACEE up to the first 300 (alphabetically) which have OMVS segments with
GIDs defined. During access checking (DAC) for UNIX resources, RACF can then base
its decisions on the user's UID and the selected groups' GIDs {IA.3::IA.1.14-R10-
RACF-2}.
 For access to LDAP LDBM resources, the LDAP server gathers a list of groups based
on the authentication data supplied by the user.
o If the user supplied an LDBM-format DN and a RACF password/phrase, LDAP
uses that DN to determine the LDBM groups to use on subsequent LDBM
access checks, unless the DN is a member of the LDAP administrative group
{IA.3::IA.1.14-R13-LDAP-1}.
o If the user supplied an SDBM-format DN and a RACF password/phrase, LDAP
retrieves the subject's group(s) from the ACEE, and converts them into SDBM-
format DNs, which become the groups to use for subsequent LDBM access
checks {IA.3::IA.1.14-R10-LDAP-2}. Additionally, if LDAP is configured for
extended group searching, LDAP derives additional groups by determining the
LDBM groups to which the SDBM user belongs {IA.3::IA.1.14-R10-LDAP-3}.
o If the user supplied a digital certificate for a SASL external bind, LDAP maps
the DN in the certificate to a RACF user ID {IA.3::IA.1.14-R10-LDAP-4}.
Subsequent processing depends on the value of the LDAP sslMapCertificate
configuration parameter.
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 If “check” is specified, the certificate DN becomes the LDBM bind DN,
and LDAP derives LDBM groups solely from that DN {IA.3::IA.1.14-R10-
LDAP-5}.
 If “add” is specified, LDAP creates an SDBM DN from the mapped RACF
user ID, and adds that SDBM DN as an alternate bind DN for
authorization processing. LDBM processing derives LDBM groups from
both the LDBM DN (in the certificate) and the SDBM DN {IA.3::IA.1.14-
R10-LDAP-6}.
 If “replace” is specified, LDAP creates an SDBM DN from the mapped
RACF user ID, and that SDBM DN becomes the only bind DN for LDBM
authorization processing. LDAP gathers the mapped user's RACF
groups, converts them to SDBM DNs, and uses them as LDBM groups
for authorization checking {IA.3::IA.1.14-R10-LDAP-7}.
 Additionally, if configured to do so, LDAP also derives LDBM groups
from the SDBM DN for the RACF user {IA.3::IA.1.14-R10-LDAP-8}.
8.1.2.11 Authentication-related differences between z/OS UNIX and
typical non-z/OS UNIX systems
There are a few security aspects that are handled different in z/OS than in “standard” UNIX
implementations. Those differences are:
i. Definition of users in /etc/passwd. In other UNIX systems, the file /etc/passwd
contains the users defined and some of the user’s attributes. Within z/OS, the file
/etc/passwd does not exist (or if it exists, does not contain any values used by the
system). All user attributes are stored in the RACF user profile and managed solely by
RACF {IA.4::IA.4.1}.
ii. Handling of the su command: the handling of the su command depends on the
existence of specific profiles in RACF.
iii. Switching to a user identity by specifying a new user ID.
The su command allows the change if the user provides the correct password
(like most other UNIX systems) {IA.4::IA.4.2}, or if the original user ID has
read access to the BPX.SRV.newuser resource profile in the SURROGAT class
{IA.4::IA.4.3}.
Note that, unlike in most other UNIX systems, this also applies to subjects
running with UID 0.
i. Switching to a superuser identity (UID 0) without specifying a new user ID.
The su command allows the change if
a) the user is already running with UID 0 {IA.4::IA.4.4}
b) the original user ID has read access to the BPX.SUPERUSER resource
profile in the FACILITY class {IA.4::IA.4.5}.
The shell started by the su command inherits the security label of the user who
issued the command (Labeled Security Mode only) {IA.4::IA.4.6}). The new user must
be authorized to the inherited security label or the su command fails (Labeled
Security Mode only) {IA.4::IA.4.7}.
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When a user executes a program that has the setuid bit set, only the effective user ID is
changed to that of the owner of the file containing the program while the real user ID
remains that of the caller {IA.4::IA.4.v111.1}. The RACF user ID is neither changed by the su
command when changing to UID 0 using the su command without specifying a user ID
{IA.4::IA.4.V1R7.1} nor by executing a program that has the setuid or setgid bit set
{IA.4::IA.4.v111.2}.
When executing the su command to a user with a non-zero UID, or when specifying the
userid and password with the su command when switching to a user with UID 0, all
credentials including the RACF user ID are reset to the new user {IA.4::IA.4.V1R7.2}.
An executable file can have additional attributes (setuid and setgid bits) used to allow a
program temporary access to files that are not normally accessible to other users. Those
permission bits sets the effective user ID or group ID of the user process executing a
program to that of the file whenever the file is run {IA.4::IA.4.V1R7.3}. The setuid and setgid
bits are only honored for executable files containing load modules or REXX execs. These bits
are not honored for shell scripts that reside in the file system {IA.4::IA.4.V1R7.4}.
When authorized to do so, a process executing in the z/OS UNIX System Services
environment can change its real, effective, and saved set user IDs or the real, effective and
saved user ID of process spawned off using dedicated system services. The following
restrictions apply:
 The process is executing with UID 0 or the current subject has the trusted or
privileged attribute {IA.4::IA.4.V1R7.5} or
 If User_ID is the same as the real UID of the process or the saved set UID, the setuid
service sets the effective UID to be the same as User_ID {IA.4::IA.4.V1R7.6}.
The RACF user ID is changed if one of the following conditions is satisfied
 The calling process is executing with an effective UID 0, the calling user ID has been
authorized to the BPX.DAEMON profile in the FACILITY class and the calling program
has been loaded from a controlled library in a clean environment {IA.4::IA.4.V1R7.7}.
 The target user ID has been successfully authenticated by the password service
{IA.4::IA.4.V1R7.8} or has SURROGAT authority to the new user ID
{IA.4::IA.4.V1R7.9}. The TOE may also allow to change the real, effective, and saved
set group IDs (GIDs) for the calling process. The following restrictions apply:
o the process is executing with UID 0 or the current RACF user ID has the
trusted or privileged attribute (\{IA.4::IA.4.V1R7.10} or
o If Group_ID is equal to the real group ID or saved set group ID of the process,
the effective group ID is set to Group_ID the process is executing with UID 0 or
the current RACF user ID has the trusted or privileged attribute
{IA.4::IA.4.V1R7.11}.
The setgid service does not change any supplementary group IDs of the calling process
{IA.4::IA.4.V1R7.12}.
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User identification and authentication are also performed by the telnet, rlogin, rsh, rexec,
and ftp z/OS UNIX services (as described in Authentication function), the LDAP server, the
HTTP Server, and the SSH daemon (sshd).
The sudo Command
With the Ported Tools for z/OS Supplementary Toolkit Feature installed, the security
administrator can create the sudoers file, and through configuration statements in that file
the administrator can allow selected users the ability to use the sudo command to run
specified UNIX commands, with specified operands, under the authority of different user IDs.
This provides a more restricted, controlled, version of the su command functionality
mentioned earlier, because the administrator can limit both the UNIX shell commands and
the command operands available, rather than allowing all UNIX shell commands as su
normally would {IA.4::IA.4-R13-SUDO-1}
The BPX.DAEMON Profile in the FACILITY Class
When the BPX.DAEMON profile is defined in the FACILITY class of RACF, z/OS allows for a
finer granularity of handling privileges of z/OS UNIX System Services.
Any superuser permitted to this profile has the daemon authority to change MVS identities
via z/OS UNIX services without knowing the target user ID’s password {IA.4::IA.4.V1R7.13}.
This identity change can only occur if the target user ID has an OMVS segment defined
{IA.4::IA.4.V1R7.14}.
If the BPX.DAEMON FACILITY class profile is defined, then z/OS UNIX will verify that the
address space has not loaded any executables that are uncontrolled before it allows any of
the following services that are controlled by z/OS UNIX to succeed:
 seteuid
 setuid
 setreuid
 pthread_security_np()
 auth_check_resource_np()
 __login()
 spawn with user ID change
 __passwd()
 __certificate()
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{IA.4::IA.4.V1R7.15}
Daemon authority is required only when a program does a setuid(), seteuid(), setreuid(), or
spawn with user ID to change the current UID without first having issued an ___certificate()
or an __passwd() call to the target user ID. In order to change the MVS identity without
knowing the target user ID’s password, the caller of these services must be a superuser.
Additionally, if a BPX.DAEMON FACILITY class profile is defined and the FACILITY class is
active, the caller must be permitted to use this profile {IA.4::IA.4.V1R7.16}. If a program
comes from a controlled library and knows the target UID’s password, or supplied the
target’s certificate, it can change the UID without having daemon authority
{IA.4::IA.4.V1R7.17}.
8.1.2.12 Assertion of User Identity
{IA.5::IA.5-R12-IDPROP-RACF-1} RACF supports specification on initACEE and RACROUTE
REQUEST=VERIFY of a distributed identity via a structure called an IDID (containing a user's
distinguished name (DN) and a domain/realm name (DC)):
• If an IDID is specified on initACEE but a RACF user ID is not specified, then initACEE
will perform a mapping operation using the IDIDMAP class to determine the
associated RACF user ID to use during RACROUTE REQUEST=VERIFY processing and
will also include the IDID information.
• If both an IDID and a RACF user ID are specified on initACEE, then initACEE will create
an ACEE for that user ID as it usually would and not perform mapping. Again, it will
include the IDID information on the RACROUTE REQUEST=VERIFY call.
• When an IDID is specified on RACROUTE REQUEST=VERIFY, RACF uses the other
parameters to create the ACEE as it normally does, but will anchor the IDID
information in the ACEE for later use during auditing.
{IA.5::IA.5-R12-IDPROP-RACF-2} RACF provides a ‘RACMAP’ command to allow the security
administrator to define ‘mapping filter rules’ to RACF that will support the mapping of
distributed user identities, as specified within the IDID data area, into RACF user IDs as
required by the customer. This new RACF command is similar to the existing RACDCERT
command, which allows the specification of mapping filter rules that RACF uses to map
distributed user identities based on the ‘subject’ and ‘issuer’ information within Digital
Certificates. But instead of being limited to only user identities within Digital Certificates, the
new command supports the definition of mapping filter rules within the IDIDMAP class based
on an x.500 representation of the user identity and the ‘Name-Space’ that the user is
defined within.
{IA.5::IA.5-R12-IDPROP-RACF-3} The RACF R_cacheserv callable service provides a function
(function code 7) that will extract a copy of the ACEE for the currently active user in the form
of a RACF environment object (aka RACO), save that RACO in a data space, and return a
context reference (ICRX) that will uniquely identify that saved RACO. Subsequently an
invoker of RACROUTE REQUEST=VERIFY can provide that ICRX and RACF will recreate the
security environment (ACEE) of the original user from the RACO or from the IDID information
in the ICRX if necessary. R_cacheserv will also allow deletion of a cached security
environment.
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{IA.5::IA.5-R12-IDPROP-RACF-5}The RACF R_cacheserv service can also return a pseudo-
userID and pseudo-password that RACF authentication functions (initACEE, RACROUTE
REQUEST=VERIFY) will subsequently accept and use to create an ACEE for the previously
specified RACF user ID with an ICTX data area cached on the earlier R_cacheserv invocation.
The pseudo-userID and pseudo-password may be used at most once on a subsequent
authentication request.
{IA.5::IA.5-R12-IDPROP-RACF-4} RACF will provide an ENF signal when an administrator has
issued an ALTUSER REVOKE or a CONNECT or REMOVE command that changes a user's
group connections, allowing applications that have cached ACEEs locally or via R_cacheserv
to remove their cache entries and recreate the ACEEs if needed.
{IA.5::IA.5-R12-IDPROP-USS-1} The UNIX System Services __passwd (BPX1PWD) and
pthread_security_np() (BPX1TLS) function allows appropriately authorized servers to assert a
user identity and create a security environment by specification of the pseudo-userID and
pseudo-password obtained via a prior authentication and use of R_cacheserv.
8.1.3 Discretionary Access Control
8.1.3.1 Access control principles
z/OS provides the Resource Access Control Facility (RACF) as the component that performs
access control between subjects acting on behalf of a user and resources protected by the
discretionary and (in Labeled Security Mode) mandatory access control policies. RACF uses
user and resource profiles it stores in the RACF database to decide if a subject has access to
a non-UNIX resource. For UNIX resources, the access permissions are carried with the
resource itself (permission bits)
All z/OS components that have to make access decisions will call RACF through a z/OS
interface. The following figure shows the flow of requests and replies within z/OS when a
request to access a protected resource is made.
A program that wants to access a resource uses a function that is part of the external
interface provided by the z/OS operating system to one of the z/OS components (1). An
example is a program that wants to open a data set.
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The z/OS component responsible for managing the resource calls the RACF component using
the internal interface to RACF (mainly the RACROUTE interface) to check the access rights of
the user that initiated the user request and passes the name and type of the resource and
the requested type of access to RACF {AC.1::AC.1.1}. The caller may also pass the ID of the
user or an explicit user security context (ACEE), or RACF obtains those values from the
security context of the user that has been established during user authentication (2)
{AC.1::AC.1.2}.
RACF extracts the user information from the security context of the user or (in a few cases)
from the user profile, extracts the resource profile from its external database or the internal
cache (3), and checks to see if the user with his current security attributes is allowed to
access the resource in the requested access mode (4 and 5).
If the resource is known to RACF, RACF returns either a “yes” or a “no” decision for the
access request {AC.1::AC.1.3}. If the resource is not known to RACF, RACF may return a
“don’t know” return code unless there are specific options set that allow RACF to take a yes
or no decision (6) {AC.1::AC.1.4}. In the case of a “don’t know” result, the resource
manager needs to make its own decision whether to allow access or not. Depending on the
decision, the resource manager will either perform or reject the access request of the user
program (7) {AC.1::AC.1.5}.
The protection philosophy of RACF is based on “profiles” that represent protected resources
but also users and groups. Profiles are organized in profile classes, where each class
represents a type of resource (such as data sets or terminals) or other entity (such as users
or groups). A profile stores attributes of the subject or object it represents.
For profiles that represent a protected resource, an access list can be assigned
{AC.1::AC.1.6}. This access list specifies the type of access subjects may have to the
resource represented by the profile.
Access control to UNIX file system objects and IPC objects are also handled by RACF, but in
the case of these objects, the access rights are stored with the object itself. RACF still
performs the access check. For details, see the description of access control for UNIX
objects.
RACF also allows LDAP clients (typically servers outside of the TOE, residing on the network)
that have authenticated using an ICTX-style DN to request RACF to perform an access check
on its own behalf or on behalf of another user (typically a client of the server making the
request). Note that these requests do not represent actual resource accesses that will occur
within the TOE, but merely allow the TOE to provide access controls to processes running
externally within the network if desired. Additionally, the client can specify any resource
class known to RACF, except DATASET, and any resource name with legal RACF syntax that
it chooses.
The LDAP client uses an LDAP extended-operation (which gets routed by the LDAP server to
the ICTX plug-in) to request this remote authorization function which can:
 Check the client's own authority to access a specified resource name in a specified
RACF resource class {AC.2::AC.2-R9-EIM-1}. This usage of the remote authorization
service requires the LDAP client to have READ authority to FACILITY resource
IRR.LDAP.REMOTE.AUTH {AC.2::AC.2-R9-EIM-2}.
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 Check a specified user's or group's authority to access a specified resource name in a
specified RACF resource class {AC.2::AC.2-R10-EIM-3}. This usage of the remote
authorization service requires the LDAP client to have UPDATE authority to FACILITY
resource IRR.LDAP.REMOTE.AUTH {AC.2::AC.2-R9-EIM-4}.
8.1.3.2 Protected resources
The protected resources considered in detail in this Security Target are:
 Data sets
 Volumes
 Devices
 Terminals
 TCP/IP connections
 Operator commands
 Programs
 Consoles
 UNIX file system objects
 UNIX IPC objects
 LDAP LDBM objects
 System logger objects
 Communications Server Policy Agent data
 Hardware management interface functions
As a general-access control system, RACF is capable of protecting a number of other
resources, but those are not considered in detail in this evaluation because it is up to the
resource manager that uses them to determine the valid resource names and the semantics
of the access control decisions. Instead, we will mention them below and later consider only
the rules regarding their administration via the RACF commands.
RACF can also protect installation-defined resource classes, which we will not consider at all
in this evaluation.
The reader should note that some other RACF classes are included in this evaluation that do
not represent “resources” but represent privileges or restrictions, where assigning “access”
to a resource in such a class to a user or a group just determines that the user or group has
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the privilege or restriction associated with the profile. Those classes and profiles are
described in the relevant subsection of the access control section in this Security Target. The
reader should also understand that granting privileges that are not described in this
document should be done with care, and only for trusted users, as those privileges may
allow administrative functions or extraordinary resource accesses.
Resource profiles of RACF are structured into an open set of “resource classes”. IBM
provides a set of resources classes used by z/OS (stored in the “static class descriptor
table”), but RACF also allows for the definition and activation of additional resource classes
using the RDEFINE or RALTER commands addressing the CDT general resource class (those
are stored in the “dynamic class descriptor table”). The dynamically defined classes need to
be “activated” using the command SETROPTS RACLIST(CDT) REFRESH. Resource classes
represent “types” of objects that are access protected by RACF. IBM supplies a default static
class descriptor table, which is structured into resources used by different components of
z/OS as well as resources used by specific other IBM products like DB2 or CICS.
General z/OS Resource Classes
IBM supplies a class descriptor table that defines classes used by z/OS or other IBM products
that use the services of RACF for controlling access to the resources they manage. The
following tables list the classes of general resources used by RACF on z/OS and used by
z/OS, DB2, and other products. Resource classes marked in red include resources that are
used by RACF internally for managing access to RACF resources or use of RACF controlled
privileges. Not all classes are used by z/OS, and some are used by products or z/OS
elements that have not been evaluated under the Common Criteria. They are listed here,
however, for completeness.
Class Name Purpose
ALCSAUTH Supports the Airline Control System/MVS (ALCS/MVS) product.
APPCLU Verifying the identity of partner logical units during VTAM session
establishment.
APPCPORT Controlling which user IDs can access the system from a given LU (APPC
port of entry). Also, conditional access to resources for users entering the
system from a given LU.
APPCSERV Controlling whether a program being run by a user can act as a server for
a specific APPC transaction program (TP).
APPCSI Controlling access to APPC side information files.
APPCTP Controlling the use of APPC transaction programs.
APPL Controlling access to applications.
CACHECLS Contains profiles used for saving and restoring cache contents from the
RACF database. See the description of the R_cacheserv RACF callable
service.
CBIND Controlling the client’s ability to bind to the server.
CDT Contains profiles for installation-defined classes for the dynamic CDT.
CFIELD Contains profiles that define the installation's custom fields.
CONSOLE Controlling access to MCS consoles. Also, conditional access to other
resources for commands originating from an MCS console.
DASDVOL DASD volumes.
DBNFORM Reserved for future IBM use.
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Class Name Purpose
DEVICES Used by MVS allocation to control who can allocate devices such as:
 Unit record devices (printers and punches) (allocated only by PSF,
JES2, or JES3)
 Graphics devices (allocated only by VTAM)
Teleprocessing (TP) or communications devices (allocated only by VTAM)
DIGTCERT Contains digital certificates and information related to them. See chapter
20 of [RACF.SAG] and the description of the RACDCERT command.
DIGTCRIT Specifies additional criteria for certificate name filters. See chapter 20 of
[RACF.SAG] and the description of the RACDCERT command.
DIGTNMAP Mapping class for certificate name filters. See chapter 20 of [RACF.SAG]
and the description of the RACDCERT command.
DIGTRING Contains a profile for each key ring and provides information about the
digital certificates that are part of each key ring. See chapter 20 of
[RACF.SAG] and the description of the RACDCERT command.
DIRAUTH Setting logging options for RACROUTE REQUEST=DIRAUTH requests.
Also, if the DIRAUTH class is active, security label authorization checking
is done when a user receives a message sent through the TPUT macro or
the TSO SEND, or LISTBC commands.
DLFCLASS The data look-aside facility.
FACILITY Miscellaneous uses. Profiles are defined in this class so resource
managers (typically elements of z/OS or z/VM) can check a user’s access
to the profiles when the user takes some action. Examples are the profiles
used to control execution of RACDCERT command functions and the
profiles used to control privileges in the z/OS UNIX environment. RACF
does not document all of the resources used in the FACILITY class by
other products. For information on the FACILITY class resources used by
a specific product (other than RACF itself), see that product’s
documentation.
FIELD Fields in RACF profiles (field-level access checking).
FSACCESS Allows control of access to the root of a zFS file system through RACF
resource profiles rather than UNIX permission bits or ACLs.
GDASDVOL Resource group class for DASDVOL class.
GLOBAL Global access checking table entry.
GMBR Member class for the GLOBAL class.
GSDSF Resource group class for SDSF class.
GTERMINL Resource group class for TERMINAL class.
GXFACILI Grouping class for XFACILIT resources.
IBMOPC Controlling access to OPC/ESA subsystems.
IDIDMAP Contains distributed identity filters created with the RACMAP command.
JESINPUT Conditional access support for commands or jobs entered into the system
through a JES input device.
JESJOBS Controlling the submission and cancellation of jobs by job name.
JESSPOOL Controlling access to job data sets on the JES spool (that is, SYSIN and
SYSOUT data sets).
KEYSMSTR Contains profiles that hold keys to encrypt data stored in the RACF
database, such as LDAP BIND passwords and DCE passwords.
LDAPBIND Contains the LDAP server URL, bind distinguished name, and bind
password.
LOGSTRM Controls system logger resources, such as log streams and the coupling
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Class Name Purpose
facility structures associated with log streams.
NODES Controlling the following on MVS systems:
1. Whether jobs are allowed to enter the system from other nodes
2. Whether jobs that enter the system from other nodes have to
pass user identification and password verification checks
NODMBR Member class for the NODES class.
OPERCMDS Controlling who can issue operator commands (for example, JES and
MVS, and operator commands).
PMBR Member class for the PROGRAM class.
PROGRAM Protects executable programs.
PROPCNTL Controlling if user ID propagation can occur, and if so, for which user IDs
(such as the CICS or IMS main task user ID), user ID propagation is not to
occur.
PSFMPL Used by PSF to perform security functions for printing, such as separator
page labeling, data page labeling, and enforcement of the user printable
area.
PTKTDATA PassTicket key class enables the security administrator to associate a
RACF secured sign-on secret key with a particular mainframe application
that uses RACF for user authentication. Examples of such applications
are IMS, CICS, TSO, z/VM, APPC, and MVS batch.
RACFEVNT Contains profiles that control the following events:
1. LDAP change log notification for changes to certain RACF profiles
New password and password phrase enveloping for a given user.
RACFHC Used by IBM Health Checker for z/OS. Contains profiles that list the
resources to check for each installation-defined health check.
RACFVARS RACF variables. In this class, profile names, which start with &
(ampersand), act as RACF variables that can be specified in profile
names in other RACF general resource classes. See [RACF.SAG],
chapter 7.
RACGLIST Class of profiles that hold the results of RACROUTE
REQUEST=LIST,GLOBAL=YES or a SETROPTS RACLIST operation.
RACHCMBR Used by IBM Health Checker for z/OS. Member class for the RACHCMBR
class.
RDATALIB Used to control use of the R_datalib callable service (IRRSDL00 or
IRRSDL64).
RRSFDATA Used to control RACF remote sharing facility (RRSF) functions.
RVARSMBR Member class for the RACFVARS class.
SCDMBR Member class for the SECDATA class.
SDSF Controls the use of authorized commands in the System Display and
Search Facility (SDSF). See also GSDSF class.
SECDATA Security classification of users and data (security levels and security
categories).
SECLABEL If security labels are used, and, if so, their definitions.
SECLMBR Member class for the SECLABEL class.
SERVAUTH Contains profiles used by servers to check a client’s authorization to use
the server or to use resources managed by the server. Also, can be used
to provide conditional access to resources for users entering the system
from a given server.
SERVER Controlling the server’s ability to register with the daemon.
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Class Name Purpose
SMESSAGE Controlling to which users a user can send messages (TSO only).
SOMDOBJS Controlling the client’s ability to invoke the method in the class.
STARTED Used in preference to the started procedures table to assign an identity
during the processing of an MVS START command.
SURROGAT If surrogate submission is allowed, and if allowed, which user IDs can act
as surrogates.
SYSMVIEW Controlling access by the SystemView for MVS Launch Window to
SystemView for MVS applications.
TAPEVOL Tape volumes.
TEMPDSN Controlling who can access residual temporary data sets.
TERMINAL Terminals (TSO or z/VM). See also GTERMINL class.
VTAMAPPL Controlling who can open ACBs from non-APF authorized programs.
WRITER Controlling the use of JES writers.
XFACILIT Miscellaneous uses. Profile names in this class can be longer than 39
characters in length. Profiles are defined in this class so that resource
managers (typically elements of z/OS) can check a user’s access to the
resources when the users take some action.
Enterprise Identity Mapping (EIM) Classes
DB2 Resource classes are mentioned here to support the evaluation of DB2. Within this Security
Target they are not used for any security function. The IBM supplied class descriptor table just
contains those classes (as well as other classes related to applications like CICS, IMS, or
Websphere), which are not used unless those applications are installed and configured to use
RACF.
DSNADM DB2 administrative authority class.
DSNR Controls access to DB2 subsystems.
GDSNBP Grouping class for DB2 buffer pool privileges.
GDSNCL Grouping class for DB2 collection privileges.
GDSNDB Grouping class for DB2 database privileges.
GDSNJR Grouping class for Java archive files (JARs).
GDSNPK Grouping class for DB2 package privileges.
GDSNPN Grouping class for DB2 plan privileges.
GDSNSC Grouping class for DB2 schema privileges.
GDSNSG Grouping class for DB2 storage group privileges.
GDSNSM Grouping class for DB2 system privileges.
GDSNSP Grouping class for DB2 stored procedure privileges.
GDSNSQ Grouping class for DB2 sequences.
GDSNTB Grouping class for DB2 table, index, or view privileges.
GDSNTS Grouping class for DB2 tablespace privileges.
GDSNUF Grouping class for DB2 user-defined function privileges.
GDSNUT Grouping class for DB2 user-defined distinct type privileges.
MDSNBP Member class for DB2 buffer pool privileges.
MDSNCL Member class for DB2 collection privileges.
MDSNDB Member class for DB2 database privileges.
MDSNJR Member class for Java archive files (JARs).
MDSNPK Member class for DB2 package privileges.
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MDSNPN Member class for DB2 plan privileges.
MDSNSC Member class for DB2 schema privileges.
MDSNSG Member class for DB2 storage group privileges.
MDSNSM Member class for DB2 system privileges.
MDSNSP Member class for DB2 stored procedure privileges.
MDSNSQ Member class for DB2 sequences.
MDSNTB Member class for DB2 table, index, or view privileges.
MDSNTS Member class for DB2 tablespace privileges.
MDSNUF Member class for DB2 user-defined function privileges.
MDSNUT Member class for DB2 user-defined distinct type privileges.
Table 13: General Resource Classes for DB2
Enterprise Identity Mapping (EIM) Classes
RAUDITX Controls auditing for Enterprise Identity Mapping (EIM).
Table 14: General Resource Classes for EIM
ICSF Resource Classes
CRYPTOZ Controls access to PKCS #11 tokens.
CSFKEYS Controls access to ICSF cryptographic keys.
CSFSERV Controls access to ICSF cryptographic services.
GCSFKEYS Resource group class for the CSFKEYS class.
GXCSFKEY Resource group class for the XCSFKEY class.
XCSFKEY Controls the exportation of ICSF cryptographic keys.
Table 15: General Resource Classes for ICSF
PSF Resource Classes
PRINTSRV Controls access to printer definitions for Infoprint Server.
Table 16: General Resource Classes for PSF
Kerberos Resource Classes
KERBLINK Mapping class for user identities of local and foreign principals.
REALM Used to define the local and foreign realms.
Table 17: General Resource Classes for Kerberos
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DFSMS Resource Classes
MGMTCLAS SMS management classes.
STORCLAS SMS storage classes.
SUBSYSNM Authorizes a subsystem (such as a particular instance of CICS) to open a
VSAM ACB and use VSAM record level sharing (RLS) functions.
Table 18: General Resource Classes for DFSMS
TSO Resource Classes
ACCTNUM TSO account numbers.
PERFGRP TSO performance groups.
TSOAUTH TSO user authorities such as OPER and MOUNT.
TSOPROC TSO logon procedures.
Table 19: General Resource Classes for TSO
UNIX System Services Resource Classes
DIRACC Controls auditing (using SETROPTS LOGOPTIONS) for access checks
for read/write access to z/OS UNIX directories. This class need not be
active to control auditing.
DIRSRCH Controls auditing (using SETROPTS LOGOPTIONS) of z/OS UNIX
directory searches. This class need not be active to control auditing.
FSOBJ Controls auditing (using SETROPTS LOGOPTIONS) for all access
checks for z/OS UNIX file system objects except directory searches.
Controls auditing (using SETROPTS AUDIT) of creation and deletion of
z/OS UNIX file system objects. This class need not be active to control
auditing.
FSSEC Controls auditing (using SETROPTS LOGOPTIONS) for changes to the
security data (FSP) for z/OS UNIX file system objects. This class need
not be active to control auditing. When this class is active, it also controls
whether ACLs are used during authorization checks to z/OS UNIX files
and directories.
IPCOBJ Controls auditing (using SETROPTS LOGOPTIONS) of access checks for
inter-process communication (IPC) objects and changes to security
information of IPC objects. Controls auditing (using SETROPTS AUDIT)
of the creation and deletion of IPC objects. This class need not be active
to control auditing.
PROCACT Controls auditing (using SETROPTS LOGOPTIONS) of functions that
look at data from, or affect the processing of, z/OS UNIX processes. This
class need not be active to control auditing.
PROCESS Controls auditing (using SETROPTS LOGOPTIONS) of changes to UIDs
and GIDs of z/OS UNIX processes. Controls auditing (using SETROPTS
AUDIT) of dubbing and undubbing of z/OS UNIX processes. This class
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need not be active to control auditing.
UNIXMAP Contains profiles that are used to map z/OS UNIX UIDs to RACF user IDs
and z/OS UNIX GIDs to RACF group names.
UNIXPRIV Contains profiles that are used to grant z/OS UNIX privileges.
Table 20: General Resource Classes for z/OS Unix
Data sets
Standard data set naming conventions
By default, RACF expects a data set name (and the data set profile name) to consist of at
least two qualifiers. RACF also expects the high-level qualifier of the data set profile name to
be either a RACF-defined user ID or a RACF-defined group name.
If an installation has chosen to define data set profiles under the standard RACF naming
conventions, they can create a group for each high-level qualifier that is not a user ID, and
permit users to protect any data set that has that high-level qualifier by giving them CREATE
authority in that group {AC.2::AC.2.1}.
Table-driven data set naming conventions
An installation can use the naming convention table to set up and enforce a data set naming
convention other than that used by RACF {AC.2::AC.2.2}. The table can:
 Supply a qualifier to be used as the high-level qualifier for authorization checking
{AC.2::AC.2.3}
 Convert data set names to RACF naming convention form for RACF use
{AC.2::AC.2.4}
 Convert names in RACF form to the installation’s format for external display
{AC.2::AC.2.5}
 Enforce a naming convention by not allowing the definition of data sets that do not
conform to an installation’s rules {AC.2::AC.2.6}
 Reduce RACF overhead by determining whether a data set is a user or group data set
An installation can create a naming convention table (module ICHNCV00), which RACF uses
to check and modify (internally to RACF) the data set name in all commands and macros
that process data set names {AC.2::AC.2.7}. An installation can use the table to selectively
rearrange data set names to “fit” the RACF convention without actually changing those
names.
Protecting data sets that have single-qualifier data set names
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If some of the data sets in an installation have names that consist of a single qualifier, one
can still RACF-protect those data sets {AC.2::AC.2.8}. To get RACF protection for single-
qualifier names, the SETROPTS command with the PREFIX operand must be issued.
This command defines a high-level qualifier to be used as a prefix for single-qualifier names
and activates the facility {AC.2::AC.2.9}. Then, when RACF processes requests for the data
set, RACF internally modifies single-qualifier names by adding the prefix, making the data
set names acceptable to RACF routines {AC.2::AC.2.10}. All SMF log records and all
messages from RACF contain the RACF-modified version of the data set name
{AC.2::AC.2.11} unless the SETROPTS REALDSN option is in effect {AC.2::AC.2-R10-RACF-
1}.
Protecting user data sets
A user data set is a data set whose high-level qualifier is a RACF user ID. The following rules
apply to user data sets:
 In general, all RACF-defined users can protect their own data sets {AC.2::AC.2.12}
 A user can RACF-protect a data set for another user under any of the following
conditions:
o The user who is protecting the data set has the SPECIAL attribute. A discrete
or generic profile can be created {AC.2::AC.2.13}.
o The user who is protecting the data set has the group-SPECIAL attribute, and
the high-level-qualifier of the data set name is a user within the group-
SPECIAL user’s scope of authority. A discrete or generic profile can be created
{AC.2::AC.2.14}.
o The user who is protecting a data set has the OPERATIONS attribute (or the
group-OPERATIONS attribute if the data set is within his scope of authority)
and is simultaneously creating the data set {AC.2::AC.2.15}.
In this case, the user can create a discrete profile:
 Through ADSP {AC.2::AC.2.16}
 By specifying the PROTECT operand on the TSO ALLOCATE command that creates the
data set {AC.2::AC.2.17}
 By specifying the PROTECT=YES OR SECMODEL= profile-name operands on the JCL
DD statement that creates the data set {AC.2::AC.2.18}
Protecting group data sets
A group data set is a data set whose high-level qualifier is a RACF group name. A RACF-
defined user can RACF-protect a group data set under any of the following conditions:
 The user has JOIN, CONNECT, or CREATE authority in the group {AC.2::AC.2.19};
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 The user has the SPECIAL attribute (or the group-SPECIAL attribute for that group)
and the request is made using the ADDSD command {AC.2::AC.2.20};
 The user has the OPERATIONS attribute and is not connected to the group
{AC.2::AC.2.21}.
Controlling the creation of new data sets
Using data set profiles, an administrator can control whether users can create (allocate) new
data sets.
For cataloged data sets, creating, deleting, or renaming the data set involves access not
only to the data set profile protecting the data set, but also to the catalog in which the data
set is cataloged {AC.2::AC.2.22}. In general, users need the following:
 To add entries to the catalog, users need authority to create the data set as specified
below and (except for SMS-managed data sets) UPDATE authority to the catalog
{AC.2::AC.2.23}.
 To delete entries from the catalog, users need ALTER authority to the protecting
profile or to the catalog {AC.2::AC.2.24}.
The following cases describe how RACF can be used to control the creation of new user and
group data sets.
A user can create a new user data set in the following situations:
 The data set is covered by an existing generic profile and the user does not have
ADSP {AC.2::AC.2.25}. The creation is allowed if (1) the user has ALTER authority to
the data set through a generic profile or global access checking, or (2) the data set is
the user’s own data set {AC.2::AC.2.26}.
 The data set name is not covered by an existing generic profile and the user does not
have ADSP and the data set is covered by the Global Access check table granting
ALTER. {AC.2::AC.2.27}
 The user has ADSP and the data set is the user’s own data set. The creation is
allowed and RACF creates a discrete profile for the data set {AC.2::AC.2.28}.
 The user has the OPERATIONS attribute. If the user has the group-OPERATIONS
attribute instead of OPERATIONS, the high-level qualifier of the new data set must be
the ID of a user who is within the scope of that group {AC.2::AC.2.29-R12-RACF}.
A user can create a new group data set in the following situations:
 The data set name is protected by an existing generic profile and the user does not
have ADSP. The creation is allowed if at least one of the following is true:
o The user has ALTER authority to the data set through the generic profile or
global access checking {AC.2::AC.2.30}
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o The user has CREATE authority in the group {AC.2::AC.2.31}
 The data set name is not covered by an existing generic profile and the user does not
have ADSP {AC.2::AC.2.32}
 The user has ADSP and the data set belongs to a group of which the user is a
member. The creation is allowed only if the user has CREATE authority in the group.
If the creation is allowed, RACF creates a discrete profile for the data set
{AC.2::AC.2.33}
 {AC.2::AC.2.36-R12-RACF}The user has the OPERATIONS attribute , or the group-
OPERATIONS attribute for the group in question (directly or via a superior group),
except when both of the following are true: The user is connected to the group with
less than CREATE authority {AC.2::AC.2.34-R12-RACF}, and the user has less than
ALTER access to the data set if it protected by a generic profile {AC.2::AC.2.35-R12-
RACF}
Data set profile ownership
Each data set profile defined to RACF requires a RACF-defined user or group as the owner of
the profile. The owner (if a user) has full control over the profile, including the access list
{AC.2::AC.2.37}.
If the owner of the data set profile is a group, users with group-SPECIAL in that group have
full control over the profile {AC.2::AC.2.38}.
Ownership of data set profiles is assigned when the profiles are defined to RACF but may be
changed later. Note that ownership of a data set profile does not mean that the owner can
automatically access that data set. To access a data set, the owner must still be authorized
by the DAC and (in Labeled Security Mode) MAC policy rules {AC.2::AC.2.39}.
Volumes
By defining profiles in the DASDVOL class, the system administrator can define non-SMS-
managed DASD volumes to RACF and authorize users to perform maintenance operations
(such as dump, restore, scratch, and rename) without having access to the data set profiles
protecting the data sets on the volume {AC.2::AC.2.40}. If a user does not have the
necessary DASDVOL authority to a non-SMS-managed volume, he or she must have the
necessary authority in the DATASET class to each of the data sets on the volume
{AC.2::AC.2.41}.
Tape volumes are protected by profiles in the TAPEVOL class in the following circumstances:
 when the RACF TAPEVOL class is active and the IEHINITT utility is used to reinitialize
a tape volume that contains a standard label {AC.2::AC.2.42-R8-1}
 when the RACF TAPEVOL class is active, and SETR NOTAPEDSN is in effect, and
TAPEAUTHDSN=NO is specified in SYS1.PARMLIB(DEVSUPxx), and the tape contains
standard labels, and a user accesses data on the tape {AC.2::AC.2.42-R8-2}.
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Special Considerations for Data on Tape
A Data file located on tape can be protected in several different ways, depending on RACF
and system options:
a) TAPEVOL class active, and SETROPTS NOTAPEDSN, and TAPEAUTHDSN=NO in
SYS1.PARMLIB(DEVSUPxx): In this mode the data is protected by the TAPEVOL profile
for the standard-labeled tape {AC.2::AC.2-R8-TAPE-1} or is unprotected if no profile
exists or the tape has no labels {AC.2::AC.2-R8-Tape-2}.
b) TAPEVOL class inactive, and SETROPTS TAPEDSN, and TAPEAUTHDSN=NO in
SYS1.PARMLIB(DEVSUPxx): In this mode the data is protected by the DATASET profile
for the data set if the tape has standard labels or is unprotected if the tape has no
labels {AC.2::AC.2-R8-TAPE-3}. However, in this mode, protection may be ineffective
for data sets with names longer than 17 characters, and the physical tape volume
labels record only the last 17 characters of a data set name. Therefore, this mode
should be used only if an active tape management system (DFSMSrmm for the
evaluated configuration) is keeping track of tape contents, and will reject the tape
volume request if the data set name does not match the name specified by the user
{AC.2::AC.2-R8-TAPE-4}.
c) TAPEVOL class active, and SETROPTS TAPEDSN, and TAPEAUTHDSN=NO in
SYS1.PARMLIB(DEVSUPxx), and with TAPEVOL profiles that contain RACF TVTOCs: In
this mode RACF verifies that the user has specified the correct data set name, and
then security for the data set is provided by the DATASET profile for the data set, if
the tape has standard labels {AC.2::AC.2-R8-TAPE-5}.
d) TAPEAUTHDSN=YES specified in SYS1.PARMLIB(DEVSUPxx): In this mode the system
will check access based on the data set name specified by the user, regardless of the
SETROPTS tape-related options in effect {AC.2::AC.2-R8-TAPE-6}.
e) TAPEAUTHF1=YES specified in SYS1.PARMLIB(DEVSUPxx) and either SETROPTS
TAPEDSN specified or TAPEAUTHDSN=YES specified in SYS1.PARMLIB(DEVSUPxx): In
this mode, in addition to the access check for the data set name specified by the
user, the system will perform an additional check for the first data set on the tape
{AC.2::AC.2-R8-TAPE-7}. Note: This mode requires an active tape management
system (DFSMSrmm for the evaluated configuration) which provides the data set
name for the first file on the tape.
Note: For systems configured in Labeled Security Mode, configuration option (a) above must
be used to ensure proper auditing of data export and import.
Devices
A user authorized to define profiles in the DEVICES class can use this class to control which
users can allocate unit record devices, teleprocessing or communications devices, and
graphics devices {AC.2::AC.2.43}. For example, the DEVICES class can be used to ensure
that only authorized users can allocate devices by name. The DEVICES class can not be used
to protect other kinds of devices, such as tape or DASD devices.
Terminals
Terminals are protected by profiles in the TERMINAL or GTERMINL class. A user must have at
least read access authority assigned to a profile representing a terminal to be able to use
the terminal {AC.2::AC.2.45}. The GTERMINL class is provided to protect a class of terminals
in the same way without the need to define discrete profiles for each terminal in the
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TERMINAL class {AC.2::AC.2.46}. User access to terminals that are not protected by a profile
in one of those classes is defined by the parameter in the TERMINAL operand in the
SETROPTS command {AC.2::AC.2.47}. If this parameter is NONE, a user can not use such
terminals to log in {AC.2::AC.2.48}. If the parameter is READ, a user can use those terminals
to log in {AC.2::AC.2.49}.
Access to terminals can also be controlled for groups of users. If the option NOTERMUACC is
defined in the group profile, users within this group can only use terminals to which they are
specifically authorized on the access list in the TERMINAL profile protecting the terminal
{AC.2::AC.2.50}.
The use of a terminal can also be restricted to specific days and a time period within those
days using the WHEN and TIME options in the RDEFINE and RALTER command
{AC.2::AC.2.51}.
If both the TERMINAL and the SECLABEL class are active, RACF checks a user’s authority to
use a terminal. When RACF checks a user’s authority to use the terminal, the user must log
on with a security label that is less than or equal to the security label of the terminal
(Labeled Security Mode only) {AC.2::AC.2.52}.
TCP/IP connections
TCP/IP is a component of the Communications Server subsystem of the TOE. TCP/IP runs as a
started task and provides the TCP, UDP, RAW, ICMP and IP functions. TCP/IP loads an INET
Physical File System into the UNIX System Services kernel to handle socket requests. TCP/IP
connects to the VTAM® component of the Communications Server subsystem of the TOE for
physical communications device management services. Up to eight instances of the TCP/IP
started task may be run concurrently on one instance of the TOE to isolate networks or
stacks by security label. Socket applications may be directed to a particular stack or may
transparently span multiple stacks.
Several TCP/IP resources can be protected by resources in the SERVAUTH class:
 Access to a particular TCP/IP stack is controlled when an application opens a socket
by read access to a profile in the form “EZB.STACKACCESS.system-name.stack-
name” where system-name is the name of the TOE image and stack-name is the job
name of the particular stack {AC.2::AC.2.53}.
 Access to a particular IP address is controlled when an application explicitly binds a
socket to a local address and when an application sends data to or receives data
from a peer address. IP addresses are configured into named security zones within
the stack using NETACCESS profile statements. Access to a particular security zone is
controlled by read access to a profile in the form “EZB.NETACCESS. system-
name.stack-name.SAF-resname” where system-name is the name of the TOE image,
stack-name is the job name of the particular stack and SAF-resname is the name
configured on the NetAccess statement {AC.2::AC.2.54}.
 Access to the intranode management network is controlled when an application
attempts to start a TCP connection, or read or write any data, that traverses the
intranode management network using an OSA-Express chpid of type OSM. Access to
the intranode management network is controlled by read access to a profile in the
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form “EZB.OSM.system-name.stack-name” where system-name is the name of the
TOE image, and stack-name is the job name of the particular stack. {AC.2::AC.2-R12-
CS-62}
TCP/IP makes point of access information available on sockets for use when processing user
login requests. This information may be requested by applications. The UNIX Systems
Services subsystem will request this information on behalf of an application when it invokes
the __poe() service. The information provided by TCP/IP includes {AC.2::AC.2.56}:
 The fully-qualified SERVAUTH resource name of the NETACCESS security zone
containing the peer IP address, if it is in a security zone.
 The TERMINAL resource name of the peer IP address, if it is an IPv4 address.
 The security label to use if the RACF option MLACTIVE is set and the peer security
zone has a SYSMULTI security label.
 Access to a particular port is controlled when an application explicitly binds a socket
to a local port. Applications binding to low ports (below 1024) must be a UNIX
superuser or APF-authorized. Port usage may also be controlled by configuring the
Port or Portrange statement in the TCP/IP profile. Control may be by user ID, job
name, or read access to a profile in the form “EZB.PORTACCESS.system-name.stack-
name.SAF-resname”, where system-name is the name of the TOE image, stack-name
is the job name of the particular stack, and SAF-resname is the name configured on
the Port or Portrange statement {AC.2::AC.2.55}. The port access functions will work
for both reserved and (if configured via PORT UNRSV) for unreserved ports
{AC.2::AC.2-R10-CS-PORT-1}.
 {AC.2::AC.2-R13-CS-DVIPA-1} If a bind call uses an IP address which is defined in a
VIPARANGE subnet, READ access to EZB.BINDDVIPARANGE.system-name.stack-
name and EZB.BINDDVIPARANGE.system-name.stack-name.SAF-name is checked.
If an ioctl call uses an IP address which is defined in a VIPARANGE subnet, READ
access to EZB.MODDVIPA.system-name.stack-name and EZB.MODDVIPA.system-
name.stack-name.SAF-name is checked.
TCP/IP performs additional access control when the RACF option MLACTIVE is set (in Labeled
Security Mode). All profiles in the SERVAUTH class must have security labels defined.
Sockets are always considered to be read/write objects so all MAC checks on SERVAUTH
profiles require equivalent security labels.
 In Labeled Security Mode: The security label on the STACKACCESS profile must be
identical to the security label of the stack job. Only applications running under an
equivalent security label may access a given stack. A stack running under the
SYSMULTI label may be accessed by applications with any security label but
communications will be allowed only between applications with equivalent security
labels {AC.2::AC.2.57}.
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 In Labeled Security Mode: The security label on the NETACCESS profile for each local
interface address must be identical to the security label of the stack job. This ensures
that all implicit address assignments are equivalent to the application security label
{AC.2::AC.2.58}.
 In Labeled Security Mode: The security label on the NETACCESS profile for each local
VIPA must be equivalent to the stack security label of the stack job and may be
SYSMULTI only when the stack job is also SYSMULTI. When SourceVIPA processing is
enabled, a VIPA with a security label equivalent to the application will be chosen as
the implicit source address {AC.2::AC.2.59}.
 In Labeled Security Mode: Communications will only be permitted when the source IP
address and the destination IP address are in NETACCESS security zones with
equivalent security labels {AC.2::AC.2.60}. Additionally, when both security zones
have SYSMULTI labels, the security label of the sending application will be recorded in
the IP header using a proprietary format. These proprietary packets are restricted to
IUTSAMEHOST links between stacks on the same TOE or XCF links between stacks on
the same sysplex {AC.2::AC.2.61}.
The Communications Server subsystem of the TOE provides numerous commands and
applications. For Labeled Security Mode: There are documented restrictions on usage and
configuration of these when RACF option MLACTIVE is set.
Operator commands
Operator commands can be protected by resources in the OPERCMDS class. Resources in
this class are the individual commands specified in the form “subsystem-name.command-
name” where subsystem-name is the name of the processing environment of the command
(JES2, RACF, or MVS, for example). Access to an operator command protected by a RACF
profile requires the appropriate access authority in the access control list of the profile for
the command {AC.2::AC.2.64}. Note that if the class is active and a command is not
protected by a profile it is not allowed to be executed.
Programs
The ability of users to execute programs can be restricted by the RACF program control
function. This feature is useful for programs operating with privileges like authorized
programs. Program control can for example be used to restrict the ability of a user to start
an authorized program from an authorized library in a way such that it executes with APF
authorization {AC.2::AC.2-V1R7-1}. Users may still have read access to the library and may
therefore copy the program into another library and execute it from this library. Although
this is possible, the program will then not execute with the privileges it has when executed
from the original library {AC.2::AC.2-V1R7.2}.
Program control (as described in this section) applies to programs residing in z/OS
partitioned data sets or libraries, not to programs stored as part of z/OS UNIX file system.
Mechanisms for program control for the z/OS UNIX subsystem are explained in another
section of this Security Target.
z/OS allows for three modes for program control: BASIC, ENHANCED and ENHANCED-
WARNING. The mode is defined by the strings 'BASIC', 'ENHANCED' or 'ENHANCED-
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WARNING' in the APPLDATA field of the IRR.PGMSECURITY profile in the FACILITY class
{AC.2::AC.2.V1R7.3}. An empty value or any other value than 'BASIC' or 'ENHANCED' will
result in the ENHANCED-WARNING mode {AC.2::AC.2.V1R7.4}. If the IRR.PGMSECURITY
profile is not defined, BASIC mode is used {AC.2::AC.2.V1R7.5}. In ENHANCED-WARNING
mode the access decisions made by the TOE are the same as in BASIC mode but a warning
message is issued whenever the access would have been denied in ENHANCED mode
{AC.2::AC.2.V1R7.6}.
The checks that RACF makes when a user makes a request to load (execute) a program are:
i. If program control has been activated with SETROPTS WHEN(PROGRAM) {AC.2::AC.2-
V1R7.7}
ii. If program control is active, RACF checks to see whether the program is protected by
a profile in the PROGRAM class {AC.2::AC.2-V1R7.8}
iii. If the program is not protected, RACF determines whether there are any data sets
currently open using PADS or whether there are any execute-controlled programs in
storage in the address space:
 If there are no such data sets or programs, RACF marks the environment dirty
(uncontrolled) and allows the user to execute the program {AC.2::AC.2-
V1R7.9}.
 If there are data sets currently opened using PADS, or programs to which the
user has only EXECUTE authority, RACF fails the request and the system
abends the task. RACF issues message ICH423I to document the execute-
controlled programs, or message ICH424I to document the PADS data sets
that caused the operation to fail. In this way, RACF prevents uncontrolled
programs from gaining access to protected data or programs inappropriately
{AC.2::AC.2-V1R7.10}.
iv. If the program is protected by a profile but the user does not have at least EXECUTE
authority to the program, RACF causes the system to abend the task because the
user is not authorized to execute the program {AC.2::AC.2-V1R7.11}.
v. If the program is protected by a profile and the user has only EXECUTE authority to
the PROGRAM profile or to the library that contains the program (when the program
is loaded from a JOBLIB, STEPLIB, or tasklib), and if the job step or TSO session is
running in ENHANCED program security mode, RACF checks whether an appropriate
program established the program environment. RACF determines if the first program
executed in the job step had the ’MAIN’ attribute, or (if necessary) if the program
invoked by TSOEXEC or IKJEFTSR had the ’MAIN’ attribute. If the program does not
have MAIN, RACF next determines if the first program run in the current task (TCB) or
the first program executed in some parent task had the ’BASIC’ attribute. If so, RACF
allows the Program control request. Otherwise, RACF fails the request and issues
message ICH429I to describe the problem and tell you what program established the
environment {AC.2::AC.2-V1R7.12}.
vi. If the user is still authorized to execute the program and the program was defined
with the PADCHK attribute, RACF checks whether any program-accessed data sets
are open.
 If no program-accessed data sets are open, RACF allows the user to execute
the program {AC.2::AC.2-V1R7.13}.
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 If program-accessed data sets are open, RACF checks the user or program
combination to verify that the combination has at least the same authority to
each data set in the list that was required when each data set was opened.
 If the user or program combination has sufficient authority to all of the opened
data sets, RACF allows the user to execute the program {AC.2::AC.2-V1R7.14}
 If the user or program combination does not have sufficient authority to all of
the opened data sets, RACF causes the system to end the task (with abend
code 306 or 806) {AC.2::AC.2-V1R7.15}.
With program control enabled, z/OS provides the ability to allow users to access data sets
which they are not allowed to access directly by using program controlled programs
{AC.2::AC.2.V1R7.16}.
The following algorithm is used to determine if a user has access to a data set via a
controlled program:
Whenever the user has the requested access to the data set as determined by normal RACF
access checking, access is granted {AC.2::AC.2.V1R7.17}.
If the user is not granted access to the data set with normal authorization checking, RACF
checks the data set’s conditional access list if program control is active and the program
currently executing is executing as a RACF-controlled program in a clean environment. RACF
authorizes the user to open the program-accessed data set with the currently executing
program if all of the following conditions are met:
• The conditional access list contains the name of the currently running program, the
name of the first program currently running in the current task (TCB), or the name of
the first program currently running in a parent task, with the requested level of
access or higher {AC.2::AC.2.V1R7.18}.
• The user’s group or user ID is associated with the program name in the conditional
access list {AC.2::AC.2.V1R7.19}.
• The current program environment (job step, or task established under TSO/E using
TSOEXEC or IKJEFTSR) is controlled. In other words, it has not loaded an uncontrolled
program. If either of these conditions are not met, the environment is considered
uncontrolled. The user’s attempt to open the program-accessed data set fails and the
task ends with abend code 913. RACF issues message ICH417I, specifying what
caused the environment to become uncontrolled {AC.2::AC.2.V1R7.20}.
• If the job step or TSO session is running in ENHANCED program security mode, one of
the following is true:
 The current environment (job step or task created by TSOEXEC or IKJEFTSR)
first ran a program defined with the ’MAIN’ attribute.
 The current program running in the current task, or the first program run in
the current task or a parent task, has the BASIC attribute. If neither of these
conditions is met, the user’s attempt to open the program-accessed data set
fails and the task ends with abend code 913. RACF issues message ICH426I,
specifying the non-MAIN program that established the current environment
{AC.2::AC.2.V1R7.21}.
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• If there is more than one controlled program running in the current environment (job
step or task created by TSOEXEC or IKJEFTSR), all of those programs defined with the
PADCHK attribute have conditional access list entries allowing them to access the
data set. If one or more programs in the environment are not authorized, the attempt
fails and the task terminates with abend code 913. RACF issues message ICH418I
specifying one or more programs that were missing from the conditional access list
{AC.2::AC.2.V1R7.22}.
• 1.If all the conditions for program access to data set are met and the requested type
of access is granted to the program by the profile protecting the data set, access is
granted {AC.2::AC.2.V1R7.23}.
Consoles
When the CONSOLE class is active and a console being used is protected by a profile in the
CONSOLE class, RACF ensures that the person attempting to logon at this console has the
proper authority to do so {AC.2::AC2.V1R7.24}. Using RACF, the use of system consoles can
be controlled {AC.2::AC2.V1R7.25}.
UNIX file system objects
UNIX file system objects in the HFS or zFS file system have their access control defined by:
 UNIX permission bits
 Access control list entries
 In Labeled Security Mode: security labels (zFS file system)
All of those access-control-related attributes of file system objects are stored with the
object. Access control lists and (in Labeled Security Mode) security labels are stored and
managed as extended attributes of the file system object and are not stored in the RACF
database {AC.2::AC.2.65}. RACF is still involved when an access decision is made to a UNIX
file system object {AC.2::AC.2.66}. The UNIX System Services subsystem of the TOE
extracts the permission bits, access control list entries and (in Labeled Security Mode) the
security label from the file system object as well as the effective user ID and (in Labeled
Security Mode) the security label of the user that performed the request and passes this
information to RACF. RACF then evaluates this information, extracts other information
relevant for the access decision from the RACF database, performs the auditing in
accordance with the audit policy defined by the system administrator and returns the access
decision to the calling UNIX System Services subsystem of the TOE {AC.2::AC.2.67}.
Besides the access control lists and (in Labeled Security Mode) the security label, additional
privileges and restrictions may be defined to allow a finer granularity. Those privileges and
restrictions are defined as profiles in the UNIXPRIV class and users can be granted those
privileges or restrictions by giving them authority to those profiles. The ones that are
considered in this Security Target are:
 SUPERUSER.FILESYS.ACL.ACLOVERRIDE
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When this profile is defined and active in RACF, a user who has been given authority to this
profile is able to override the access control defined by the access control lists for z/OS UNIX
file system objects.
In z/OS, a UNIX superuser can access all z/OS UNIX files, but is still bound by his rights
defined in RACF with respect to z/OS data sets and other resources {AC.2::AC.2.68}. In
Labeled Security Mode, a z/OS UNIX superuser is also bound by the mandatory access
control rules when accessing z/OS UNIX files {AC.2::AC.2.69}.
z/OS UNIX IPC objects
z/OS UNIX IPC objects are subject to discretionary access control. The permission bits
associated with the IPC object define the discretionary access to those objects. The
permission bits are determined by the creator of the IPC object and are saved in-memory by
the UNIX Kernel. For security claims see DAC for UNIX objects.
LDAP LDBM objects
LDAP LDBM objects (objects in an LDBM back end for a z/OS LDAP server) exist in a single
administrator-configured file (LDBM database) in the UNIX file system for each suffix the
LDBM back end supports in each server {AC.2::AC.2-R8-LDAP-1} and are subject to
discretionary access control by the LDAP server itself (not by RACF) using standard LDAP
ACLs {AC.2::AC.2-R8-LDAP-2}and/or LDAP Filter ACLs {AC.2::AC.2-R12-LDAP-13}. LDAP
objects are organized hierarchically in a tree format, and each object has a distinguished
name (DN) which both names the object and locates it within the tree {AC.2::AC.2-R8-LDAP-
3}.
[Note: LDAP also supports a CDBM back end, containing configuration information for the
LDAP server. The CDBM back end looks and operates like the LDBM back end, except that it
contains a directory information tree that holds LDAP configuration information and specifies
the members of the LDAP administrative group and optionally their LDAP administrative
roles. Members of the LDAP administrative group have specific access rights based on their
LDAP administrative roles to the configuration data in the directory information tree, as
described later in the LDAP Management section. Statements in this document about how
LDBM works apply to CDBM, too, except where otherwise indicated.]
Users do not have direct access to the data (in the sense that they have for, say, data
access via FTP or NFS). Rather, users make requests to the LDAP server specifying the
named objects to retrieve, and the server interprets those requests, locates the named
objects, and acts on them if the user has the proper authority {AC.2::AC.2-R8-LDAP-4}.
Users who have not performed a bind or have performed an anonymous bind are called
unauthenticated or anonymous. There is no difference between the access rights given to
unauthenticated and anonymous user {AC.2::AC.2-R8-LDAP-6}. Administrators may allow
access to anonymous users {AC.2::AC.2-R8-LDAP-7} or deny access to anonymous users
{AC.2::AC.2-R8-LDAP-8} anywhere they choose within the LDAP tree {AC.2::AC.2-R8-LDAP-
9}. By default anonymous access is allowed {AC.2::AC.2-R8-LDAP-10}.
For further information see Algorithm to check for DAC access to LDAP LDBM objects.
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System Logger objects
System logger resources, such as log streams and the coupling facility structures associated
with them are subject to discretionary access control. For more information about those
objects and RACF profiles used to protect them, see the section on the management of
system logger objects in the management section
Communications Server Policy objects
Communications Server Policy objects can be read by users that have at least read access to
the profiles protecting those objects. For more information about those objects and the RACF
profiles that protect them see the section on the Communications Server Policy Agent later
in this document.
Hardware Management Interface Functions
The System z processors provide privileged instructions that allow an operating system
running in a logical partition (LPAR) to perform hardware management functions (e.g.,
activating or deactivating processors, IPLing an operating system into an LPAR, adjusting
LPAR performance characteristics, adjusting LPAR definitions, etc.) When defining an LPAR
to PR/SM an administrator specifies whether the LPAR can control other LPARs by setting the
Cross-Partition Authority Flag in the new LPAR definition. LPARs without that flag set can not
control other LPARs {AC.2::AC.2-R11-BCPii-1}.
z/OS provides a function called BCPii which makes hardware management functions
available to authorized (APF-authorized, or supervisor state or having a PKM allowing system
key (0-7)) programs {AC.2::AC.2-R13-BCPii-2}. After the previous authorization check
succeeds, BCPii also uses RACF resources in the FACILITY class to control which users can
connect to it and to determine which users can use the hardware management interfaces:
 The HWICONN function allows an application to establish a logical connection to a
Central Processor Complex (CPC), a CPC image (LPAR), a Capacity Record, different
types of activation profiles, or administrator-defined image groups. After establishing
the connection the application can use other services to perform operations related
to that CPC, image, capacity record, activation profile, or image group.
When the application is done with its processing, it would use the HWIDISC function
to disconnect.
Use of these functions requires READ access to HWI.APPLNAME.HWISERV
{AC.2::AC.2-R11-BCPii-3}. Then, for HWICONN users also need:
o READ access to HWI.TARGET.netid.nau to establish a CPC, image group, or
activation profile connection {AC.2::AC.2-R13-BCPii-4};
o READ access to HWI.TARGET.netid.nau.imagename to establish an image
connection {AC.2::AC.2-R11-BCPii-5}; or
o READ access to HWI.CAPREC.netid.nau.caprecid for capacity record
connections {AC.2::AC.2-R11-BCPii-6}.
 The HWIDISC function releases the logical connection between an application and a
Central Processor Complex (CPC), a CPC image (LPAR), a Capacity Record, different
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types of activation profiles, or administrator-defined image groups.
Use of HWIDISC requires READ access to HWI.APPLNAME.HWISERV {AC.2::AC.2-R13-
BCPii-25} and also:
o READ access to HWI.TARGET.netid.nau to release a CPC, image group, or
activation profile connection {AC.2::AC.2-R13-BCPii-26};
o READ access to HWI.TARGET.netid.nau.imagename to release an image
connection {AC.2::AC.2-R13-BCPii-27}; or
o READ access to HWI.CAPREC.netid.nau.caprecid for capacity record
connections {AC.2::AC.2-R13-BCPii-28}.
 The HWIQUERY function allows an application to retrieve information about Hardware
Management Console (HMC) managed objects associated with Central Processor
Complexes (CPCs), CPC images (LPARs), administrator-defined image groups,
capacity records, or different types of activation profiles.
Use of HWIQUERY requires READ access to FACILITY resource
HWI.APPLNAME.HWISERV {AC.2::AC.2-R11-BCPii-7} and also
o READ access to HWI.TARGET.netid.nau for CPC connection, image group, or
activation profile queries {AC.2::AC.2-R13-BCPii-8};
o READ access to HWI.TARGET.netid.nau.imagename for image queries
{AC.2::AC.2-R11-BCPii-9};
o READ access to HWI.CAPREC.netid.nau.caprecid for capacity record queries
{AC.2::AC.2-R11-BCPii-10}
 The HWICMD function allows an application to perform a command against a
Hardware Management Console (HMC) managed object associated with Central
Processor Complexes (CPCs), CPC images (LPARs) and capacity records.
Administrator-defined image groups can be utilized to target multiple images with a
single command.
Use of HWICMD requires READ access to FACILITY resource HWI.APPLNAME.HWISERV
{AC.2::AC.2-R11-BCPii-11} and also
o CONTROL access to HWI.TARGET.netid.nau for ConnectTokens representing
CPC or image group connections {AC.2::AC.2-R13-BCPii-12};
o CONTROL access to HWI.TARGET.netid.nau.imagename for ConnectTokens
representing image connections {AC.2::AC.2-R11-BCPii-13};
o CONTROL access to HWI.TARGET.netid.nau.imagename for all individual
images within the image groupfor a ConnectToken that represents an
administrator-defined image group {AC.2::AC.2-R13-BCPii-30}.
 The HWILIST function allows an application to retrieve Hardware Management
Console (HMC) and/or Hardware Management Interface (HWI) configuration-related
information. Depending on which information is requested, the data returned by this
service can be used on subsequent HWI service calls to connect to a Central
Processor Complex (CPC), image (LPAR), administrator-defined image group,
Capacity record (CAPREC), Reset activation profile, Image activation profile, or Load
activation profile, or to register for the proper events (HWIEVENT callable service).
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Use of HWILIST requires READ access to FACILITY resource HWI.APPLNAME.HWISERV
{AC.2::AC.2-R11-BCPii-14} and also
o READ access to the HWI.TARGET.netid.nau for each non-local CPC to be listed
{AC.2::AC.2-R11-BCPii-15};
o READ access to the HWI.TARGET.netid.nau.imagename for each image to be
listed on a CPC or within an image group {AC.2::AC.2-R13-BCPii-16};
o READ access to the HWI.TARGET.netid.nau for each CPC whose activation
profiles are to be listed {AC.2::AC.2-R11-BCPii-17};
o READ access to the HWI.CAPREC.netid.nau.caprecid for each CPC capacity
record to be listed {AC.2::AC.2-R11-BCPii-18};
o READ access to the HWI.TARGET.netid.nau for each CPC whose events are to
be listed {AC.2::AC.2-R11-BCPii-19};
o READ access to the HWI.TARGET.netid.nau.imagename for each image whose
events are to be listed {AC.2::AC.2-R11-BCPii-20}.
o READ access to HWI.TARGET.netid.nau for each CPC for which the list of
image groups is requested {AC.2::AC.2-R13-BCPii-29}.
 The HWIEVENT function allows an application to register for notification of hardware
and software events related to a CPC or image, or to delete such a registration.
Use of HWIEVENT requires
o READ access to HWI.TARGET.netid.nau for a ConnectToken representing a
CPC connection {AC.2::AC.2-R11-BCPii-23};
o READ access to HWI.TARGET.netid.nau.imagename for a ConnectToken
representing an image connection {AC.2::AC.2-R11-BCPii-24}.
 The HWISET function allows an application to change or set data for Hardware
Management Console (HMC) managed objects associated with Central Processor
Complexes (CPCs), CPC images (LPARs), or activation profiles.
Use of HWISET requires requires
 READ access to FACILITY resource HWI.APPLNAME.HWISERV {AC.2::AC.2-R11-
BCPii-27} and also UPDATE access to HWI.TARGET.netid.nau for values related
to a CPC or an activation profile {AC.2::AC.2-R11-BCPii-21};
 UPDATE access to HWI.TARGET.netid.nau.imagename for image-related values
{AC.2::AC.2-R11-BCPii-22}.
Mandatory Access Control (Labeled Security Mode only)
Label based mandatory access control is supported by z/OS. User profiles may contain one
or two SECLABEL names, representing defaults for that user (one for TSO/E, and one for
other applications) which are the name of profiles in the SECLABEL class. Each profile in the
SECLABEL class contains a security classification consisting of a hierarchical security level
and a set of non-hierarchical categories. The values for the levels and the categories are
defined by the system administrator {AC.3::AC.3.1}. z/OS supports more than 8 levels and
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more than 60 categories {AC.3::AC.3-R12-RACF-1}. The system administrator can then also
define resources in the SECLABEL resource class as a combination of one security level and
zero or more categories. Such a resource is called a “security label”.
The system defines a set of predefined security labels:
 SYSHIGH
This label consists of the highest security level and all categories defined for the system
 SYSLOW
This label consists of the lowest security level defined for the system and no categories
 SYSNONE
This is used for resources that need to be read and written by users with different security
labels. It needs to be reserved for resources that can only be accessed in a controlled way
using trusted programs to avoid a breach of the information flow policy
 SYSMULTI
This is used for resources that support a range of security labels. It needs to be reserved for
resources controlled by trusted programs. Administrators can also be allowed to operate as
SYSMULTI. An organization should apply great care when assigning and using this option
z/OS enforces the rules of the Bell-LaPadula model for mandatory access control:
 a subject has read access to an object when:
o the security level of the subject is higher or equal to the security level of the
object
o the set of categories of the subject includes the set of the categories of the
object
o read access is allowed by the discretionary access control rules
{AC.3::AC.3.2}
 a subject has write (update or control) access to an object when
o the security level of the subject is lower or equal to the security level of the
object
o the set of categories of the object includes the set of categories of the subject
o write (update or control) access is allowed by the discretionary access control
rules {AC.3::AC.3.3}
 a subject has alter access to an object when:
o the security label of the subject and the security label of the object are
identical
o the user has ALTER access according the discretionary access control rules
{AC.3::AC.3.4}
z/OS prohibits the modification of a security label of a resource unless the system is in a
state that allows to the activity to be performed in a secure way. This prohibits unauthorized
flow of information due to users operating on a resource while the security label of the
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resource is changed. A change of security labels is restricted to users with the SPECIAL
attribute {AC.3::AC.3.V1R7.3}.
The following types of resources are subject to mandatory access control:
 Data sets {AC.3::AC.3.5}
 Volumes (DASD and tape) {AC.3::AC.3.6}
 Devices {AC.3::AC.3.7}
 Terminals {AC.3::AC.3.8}
 TCP/IP connections {AC.3::AC.3.9}
 UNIX file system objects (for zFS file systems and read-only HFS file systems)
{AC.3::AC.3.11}
 UNIX IPC objects {AC.3::AC.3.12}
LDAP LDBM objects are not subject to mandatory access control in the same way as other
resources. Rather, a complete LDBM database has a single SECLABEL, neither SYSMULTI nor
SYSNONE, derived from the label of the UNIX file that contains the database {AC.3::AC.3-R8-
LDAP-1}. The LDAP/LDBM server runs with a specific security label, matching that of the
database it will read/write, and serves data with that specific label to users with the same
label {AC.3::AC.3-R8-LDAP-3}. This satisfies the overall data flow requirements of MAC
processing. To serve data with different labels, the administrator may configure multiple
LDAP/LDBM servers, each running with the appropriate label, and the client must connect to
the appropriate server {AC.3::AC.3-R8-LDAP-2}.
Printers (as examples of devices) and terminals can be restricted to the security labels
allowed to be used with them {AC.3::AC.3.13}. This allows for example to restrict user logon
or printer output with critical security labels to defined terminals resp. printers.
Each page of printer output is labeled with the security label of the subject that initiated the
output. The printed security label is in human readable format {AC.3::AC.3.14}. The exact
text of this label can be defined during system configuration {AC.3::AC.3.15}.
Communication channels within a TOE, even for a TOE consisting of multiple systems
coupled into a sysplex can be multi-level, whereas other communication channels are
assigned a single security label {AC.3::AC.3.16}.
A user can define the security label of a session when he performs his TSO login or when
submitting a batch job {AC.3::AC.3.17}. At that time he can specify the security label of the
session / job to any security label assigned for him by the system administrator
{AC.3::AC.3.18}. A user needs to start a new session or job when he wants to work with a
different security label (from the set of security labels allowed for him). In all other cases the
security label is defined by the user’s default label, by the port-of-entry or by the application
{AC.3::AC.3.19}. The user’s security label can be restricted by the allowed security label for
the port-of-entry or it can be restricted by the application he is connecting to.
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Data can be exported with its labels attached by storing the data in a z/OS UNIX zFS file
system {AC.3::AC.3.20}. Each zFS file system is implemented within a single z/OS data set.
To be able to create files and directories with different security labels in the zFS file system,
the z/OS data set hosting the zFS file system must be labeled as SYSMULTI {AC.3::AC.3.21}.
When the z/OS data set containing the zFS file system is exported, all the security labels
associated with the files and directories in this zFS file system are exported because they
are included as extended attributes in the i-nodes of the file system {AC.3::AC.3.22}. The
importing system needs to define the security labels compatible with the exporting system
to ensure that the security labels are interpreted consistently.
A system administrator can allow a user to bypass the mandatory access control rules. To do
this, the administrator needs to define the profile IRR.WRITEDOWN.BYUSER in the FACILITY
class and give the user at least READ authority to this profile. A user with this privilege can
then activate the ability to downgrade using the RACPRIV command
{AC.3::AC.3.23}.Discretionary access control
8.1.3.3 Discretionary Access Control
Discretionary access control (DAC) applies to all system resources, but the implementation
differs depending on the type of resource. This evaluation considers MVS (non-UNIX)
resources, UNIX resources, and LDAP LDBM resources. RACF provides the discretionary
access controls for MVS and UNIX resources; the LDAP server provides the discretionary
access controls for LDAP LDBM objects. See the sections above on the different profiles for
details on what is stored in those profiles.
8.1.3.4 DAC for MVS resources
RACF controls the types of access to all MVS (non-UNIX, non-LDAP) resources. The access
types are ordered hierarchically, an access type listed higher in the list implies all the access
types lower in this list (except for NONE access). The full semantics of each access type are
defined by the resource manager. The semantics for MVS data sets are:
 ALTER
ALTER allows users to read, update, delete, rename, move, or scratch the data set.
When specified in a discrete profile, ALTER allows users to read, alter, and delete the profile
itself including the access list {AC.4::AC.4.1}.
ALTER does not allow users to change the owner of the profile using the ALTDSD command
{AC.4::AC.4.2}. However, if a user with ALTER access authority to a discrete data set profile
renames the data set, changing the high-level qualifier to his or her own user ID, both the
data set and the profile are renamed, and the OWNER of the profile is changed to the new
user ID {AC.4::AC.4.3}.
When specified in a generic profile, ALTER gives users no authority over the profile itself
{AC.4::AC.4.4}.
 CONTROL
For VSAM data sets, CONTROL is equivalent to the VSAM CONTROL password; that is, it
allows users to perform improved control interval processing. This is control-interval access
(access to individual VSAM data blocks), and the ability to retrieve, update, insert, or delete
records in the specified data set {AC.4::AC.4.5}.
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For non-VSAM data sets, CONTROL is equivalent to UPDATE {AC.4::AC.4.6}.
 UPDATE
Allows users to read from, copy from, or write to the data set {AC.4::AC.4.7}. UPDATE does
not, however, authorize a user to delete, rename, move, or scratch the data set
{AC.4::AC.4.8}.
 READ
Allows users to access the data set for reading only {AC.4::AC.4.9}. (Note that users who
can read the data set can copy or print it.)
 EXECUTE
For a private load library, EXECUTE allows users to load and execute, but not to read or copy
programs (load modules) in the library {AC.4::AC.4.10}.
 NONE
The specified user or group is not permitted to access the resource or list the profile
{AC.4::AC.4.11}.
These access types can be defined per user, group or for all users not addressed specifically
by a user or group access entry (“universal access”) {AC.4::AC.4.12}. It is also possible to
specify ID(*) in an ACL, which then applies to all RACF defined users, while the value for
UACC applies to users not defined in RACF {AC.4::AC.4.13}. To modify those entries (as well
as other parts of the resource profile) a user must be the owner of the profile, have ALTER
access to the discrete profile of the resource or must have the SPECIAL attribute in his user
profile {AC.4::AC.4.14}.
The access lists defined in a profile can be either a standard access lists, allowing access in
general or a conditional access lists allowing access under defined conditions. Possible
conditions are:
 the user must be logged on using a defined terminal that the user has been granted
access to {AC.4::AC.4.15}
 the user must be logged on to a defined console {AC.4::AC.4.16}
 the batch job requesting access must have been submitted from a defined JES input
device {AC.4::AC.4.17}
 the user must have entered the system from a defined network port {AC.4::AC.4.18}
 the resource manager has asserted a criteria, such as the name of an SQL role
(SQLROLE), which applies to this check, on the authorization request (note: this
applies only to a FASTAUTH type of authorization check) {AC.4::AC.4-R8-RACF-1}.
Access to resources can be controlled by discrete resource profiles or generic profiles for a
set of resources of the same type. Discrete profiles protect one single resource (e. g. one
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data set) while generic profiles can be used to define a whole set of resources and protect
them using a single profile based on patterns in the resource name. Whenever a discrete
profile exists for a resource it has precedence over a generic profile that also would apply for
the resource {AC.4::AC.4.19}. If more than one generic profiles would apply, z/OS always
chooses the most specific profile applicable based on a matching algorithm {AC.4::AC.4.20}.
The access types above also apply to MVS resources other than data sets (called general
resources). However while the usages remain hierarchical in definition (ALTER includes
UPDATE, UPDATE includes READ, etc.) the interpretation and usage of the access types is
the responsibility of each resource manager. For most resource managers and resources,
the meaningful access types are NONE (the user/group has no access) or READ (the
user/group does have access). For most cases access levels higher than READ convey no
added authority (except that ALTER allows administration of a discrete profile). In specific
cases the resource manager may treat UPDATE, CONTROL, and ALTER as granting additional
authority. This security target and evaluation will not address all of those cases.
Algorithm to check for DAC access to MVS resources
RACF performs the following checks to identify, if a subject has the requested type of access
to an object protected by RACF. This algorithm is performed after RACF has checked that the
resource is protected by RACF and (in Labeled Security Mode) after the checks for the
mandatory access control have been performed:
i. If users attempt to access their own resources, RACF grants the request
{AC.4::AC.4.43}. For example:
 For tape and DASD data sets, if the user ID of the requesting user is the high-
level qualifier of the data set name, RACF grants the request
 For spool data sets, if the JESSPOOL class is active, RACF compares the user ID
and node of the requester with the user ID and node of the creator of the
spool data set (using the security token). If the user IDs match, RACF grants
the request.
ii. If the resource manager has performed the authorization check using RACROUTE
REQUEST=FASTAUTH (rather than RACROUTE REQUEST=AUTH) and in addition has
specified AUTHCHKS=CRITONLY for this check, and has specified a criteria value
using the CRITERIA keyword, RACF uses only the criteria-related conditional access
list entries to make the determination, and skips to the criteria checking step below
{AC.4::AC.4-R8-RACF-2}.
iii. RACF checks the user’s access authority in the standard access list. If the user is in
the list and if the specified access authority is sufficient to allow access, RACF grants
the request {AC.4::AC.4.44}. If the user is in the list and if the specified access
authority is less than the requested access, RACF continues processing at Step 7
(conditional access list checking) {AC.4::AC.4.45}. This prevents access based on
ID(*), UACC, or the OPERATIONS attribute.
This could happen if, for example, user JOE requests UPDATE access, and the
standard access list includes ID(JOE) ACCESS(READ).
iv. RACF determines whether the user has access to the resource because the user is a
member of a group and the group is on the standard access list {AC.4::AC.4.46}.
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Which group is used depends on whether list-of-groups processing is in effect. (List-
of-groups processing is in effect if the SETROPTS command has been issued with the
GRPLIST operand.)
If list-of-groups processing is not in effect, RACF uses only the user’s current connect
group {AC.4::AC.4.47}.
If list-of-groups processing is in effect, RACF finds all of the groups to which the user
is connected that are also in the access list. Of these groups, RACF uses the group
that has the highest access authority to the resource {AC.4::AC.4.48}. (For example,
assume that a user is a member of groups A, B, and C. If group A has NONE access
authority, group B has READ access authority, and group C has UPDATE access
authority, RACF uses group C to determine the user’s access.)
If the highest access authority is sufficient to allow the requested access, RACF
grants the request. If the highest group that was found in the list does not have the
requested authority, RACF continues processing at Step 8 {AC.4::AC.4.49}
(conditional access list checking). This prevents access based on ID(*), UACC, or the
OPERATIONS attribute.
v. If a user ID of * is found on the standard access list, the current user is defined to
RACF without the RESTRICTED attribute, and the access authority granted to * is:
 Sufficient to allow the requested access, RACF grants the request
{AC.4::AC.4.50}
 Not sufficient to allow the requested access, RACF continues processing at
Step 7 {AC.4::AC.4.51} (OPERATIONS attribute checking)
vi. If the universal access authority (UACC) for the resource provides sufficient access
authority and the requesting user is not defined with the RESTRICTED attribute, RACF
grants the request {AC.4::AC.4.52}
vii. If the requesting user has the OPERATIONS attribute (or group-OPERATIONS if the
resource is within the scope of that group) and OPERATIONS access is allowed for the
class, RACF grants the request {AC.4::AC.4.53}
viii.RACF checks the user’s access authority in the conditional access list specified with
WHEN(TERMINAL), WHEN(CONSOLE), WHEN(SERVAUTH), or WHEN(JESINPUT). If the
user is in the list, if the user meets the specified condition (such as logged on at the
specified terminal), and if the specified access authority is sufficient to allow access,
RACF grants the request. If the user is in the list with insufficient authority RACF
continues processing at step 11. {AC.4::AC.4-R12-RACF-54}
ix. RACF determines whether the user has access to the resource because the user is a
member of a group that meets a condition specified on the conditional access list
specified with WHEN(TERMINAL), WHEN(CONSOLE), WHEN(SERVAUTH), or
WHEN(JESINPUT).
Which group is used depends on whether list-of-groups processing is in effect.
If the group to be used according to the preceding rules has sufficient access
authority to allow the requested access, RACF grants the request {AC.4::AC.4.55}. If
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none of the user’s groups has sufficient authority, RACF continues with the next step.
x. If a user ID of * is found on the conditional access list specified with
WHEN(TERMINAL), WHEN(CONSOLE), WHEN(SERVAUTH), or WHEN(JESINPUT), and if
the current user is defined to RACF without the RESTRICTED attribute, and if the
current user meets the specified condition (such as logged on at the specified
terminal), and the access authority granted to * is sufficient to allow the requested
access, RACF grants the request {AC.4::AC.4.56}
xi. RACF checks the user’s access authority in the conditional access list specified with
WHEN(PROGRAM). If the user is in the list, if the user meets the specified condition
(such as running the specified program), and if the specified access authority is
sufficient to allow access, RACF grants the request {AC.4::AC.4.57}.
Note: For DASD data sets, if program control is active and a controlled program is
executing, RACF performs authorization checking for program access to data sets. If
the user/program combination is in the conditional access list with sufficient authority
to allow access to the data sets, RACF grants the request {AC.4::AC.4.58}.
xii. RACF determines whether the user has access to the resource because the user is a
member of a group that meets a condition specified on the conditional access list
(such as running a specified program). Which group is used depends on whether list-
of-groups processing is in effect.
If the group to be used according to the preceding rules has sufficient access
authority to allow the requested access, RACF grants the request {AC.4::AC.4.59}. If
the group is in the list and if the specified access authority is NONE, RACF denies the
request {AC.4::AC.4.60}.
xiii.If a user ID of * is found on the conditional access list specified with
WHEN(PROGRAM), and if the current user is defined to RACF without the RESTRICTED
attribute, and if the current user meets the specified condition (such as logged on at
the specified terminal or running the specified program), and the access authority
granted to * is sufficient to allow the requested access, RACF grants the request
{AC.4::AC.4.61}
xiv.Criteria Checking: For RACROUTE REQUEST=FASTAUTH, if the resource manager has
asserted an SQL role name (SQLROLE) via the CRITERIA keyword, RACF checks for
authority (via the user ID, a group, or * (for non-RESTRICTED users)) in the
conditional access list specified with WHEN(SQLROLE(…)), and if the specified access
authority is sufficient to allow access, RACF grants the request {AC.4::AC.4-R8-RACF-
3}. If the resource manager has also specified AUTHCHKS=CRITONLY, and this step
did not grant access, RACF denies the request {AC.4::AC.4-R8-RACF-4}.
xv. For access to uncataloged data sets, if SETROPTS CATDSNS is in effect, and none of
the following is true, then RACF denies the request {AC.4::AC.4.62}:
 The data set is newly-created in this job, or is a system temporary data set;
 The data set is protected by a discrete profile;
 The data set is cataloged in the Master catalog;
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 The user has access to FACILITY resource ICHUNCAT.dataset-name (truncated
to 39 characters total, if needed);
 The user has the SPECIAL attribute
xvi.For the DATASET class, if no profile is found and the SETROPTS
PROTECTALL(FAILURES) option is in effect, RACF denies the request {AC.4::AC.4.63}.
If none of the above steps has granted access and the call to RACF has provided a nested
ACEE and RACF is called with RACROUTE REQUEST=FASTAUTH and the object is eligible for
nested ACEE processing, the algorithm for both mandatory and discretionary access control
is repeated using the user ID specified in the nested ACEE {AC.4::AC.4-V1R7.1}. If audit is
configured to audit the access attempt, both user IDs (the original and the nested) are
contained in the audit record {AC.4::AC.4.V1R7.2}.e f
Event Notifications generated by RACF
RACF can send an ENF type 62 signal to listeners when a SETROPTS RACLIST command
affects in-storage profiles used for authorization checking. RACF sends a signal when a
SETROPTS RACLIST, SETROPTS NORACLIST, or SETROPTS RACLIST REFRESH command is
issued for a class, activating, deactivating, or updating the profiles. Signals are sent for a
class in the static class descriptor table if SIGNAL=YES was specified on the ICHERCDE
macro that defined the class. Signals are sent for a class in the dynamic class descriptor
table if SIGNAL(YES) was specified on the CDTINFO keyword of the RDEFINE or RALTER
command that defined the class.{SM.3::SM.3-R12-RACFEAL5-33}
These signals enable an application or resource manager that uses those classes of
resources to react appropriately after an administrator implements a change that may affect
subsequent security decisions by the application or resource manager.
DAC for System Logger Objects in the LOGSTRM class
DAC for System Logger objects in the LOGSTRM class uses the basic MVS DAC algorithm
explained above. The DAC algorithms apply in two cases:
• application programs that merely need to read or write to a log stream. The standard
MVS DAC algorithm applies, using READ access for reading only, or UPDATE access
for reading and writing, to resource log_stream_name in the LOGSTRM class
{AC.4::AC.4-R10-Logger-1}.
• application programs that want to perform system management functions: defining,
deleting, or updating the log stream definitions. The Security Management section
will cover those usages.
8.1.3.5 DAC for UNIX objects
DAC controls for UNIX objects involve the user’s effective UID and effective GID (which may
be different from the user’s real UID and real GID) {AC.4::AC.4-R8-USS-1} and the user’s
supplemental GIDs. If the user is connected to 5 groups, and 3 of them have GIDs, then he
would have one real GID and 2 supplemental GIDs {AC.4::AC.4-R8-USS-2}.
DAC checking for UNIX file objects (files, directories) involves permission bits that specify
the permissions (read, write, execute/search) separately for the object’s owner, the owning
group, and everyone else (the world), and optional access list entries (ACLs) with similar
permission settings.
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DAC checking for UNIX IPC objects (semaphores, shared memory) involves only permission
bits.
Algorithm to check DAC access to UNIX file system objects
The following algorithm is used in the evaluated configuration to check the access to UNIX
file system objects. The checks are performed by RACF using the effective user and group ID
respectively, except as noted below.
• (Step performed in Labeled Security Mode only) Access to the file system object must
be allowed by the mandatory access control function. If not, access is denied
{AC.4::AC.4.21}.
• If the FSACCESS class is active and SETROPTS RACLISTed, and if the user is accessing
the root directory in a mounted zFS file system (but not the system root directory),
then if the MVS data set name of the file system container is protected by a profile in
the FSACCESS class the user must have UPDATE access to that FSACCESS profile or
the request will fail. Note that this is a standard RACF access check using the
capabilities described above for DAC for MVS resources {AC.4::AC.4-R13-UNIX-1}.
• If the user has the RACF AUDITOR attribute, and read or search access for a directory
is requested, access is granted {AC.4::AC.4.22}.
• If the user has UID(0), or has the TRUSTED or PRIVILEGED attribute, then access is
granted automatically unless the user is executing a file. If the user is executing a
file, access is denied only if none of the permissions bits grant execute access, and, if
an ACL is present and the FSSEC class is active, no ACL entry grants execute access.
Otherwise, access is granted {AC.4::AC.4.23}.
• If the user does not have search permission to all directories in the path of the file
system object, access is denied {AC.4::AC.4.24}.
• If the UID matches the file owner UID, the file’s “owner” permission bits are checked.
If the “owner” bits allow the requested access, then access is granted
{AC.4::AC.4.25}. If the UID matches the file owner UID and the owner bits do not
allow the requested access, go to Step 15 {AC.4::AC.4.26}.
• If the FSSEC class is active, and an ACL exists, and there is an ACL entry for the
requesting UID, then the permission bits of that ACL entry are checked. If the ACL
entry allows the requested access, then access is granted {AC.4::AC.4.27}.
Otherwise, if the ACL for the UID exists, but does not allow access, go to Step 14
{AC.4::AC.4.28}.
• If the GID matches the file owner GID, the file’s “group” permission bits are checked.
If the “group” bits allow the requested access, then access is granted
{AC.4::AC.4.29}.
• If the FSSEC class is active, and an ACL exists, and there is an ACL entry for the
requesting GID, then the permission bits of that ACL entry are checked. If the ACL
entry allows the requested access, then access is granted {AC.4::AC.4.30}. If not,
then the next ACL entry is checked until there are no more entries {AC.4::AC.4.31}.
• If any of the user’s supplemental GIDs match the file owner GID, the file’s “group”
permission bits are checked. If the “group” bits allow the requested access, then
access is granted {AC.4::AC.4.32}.
• If the FSSEC class is active, and an ACL exists, and there is an ACL entry for any of
the user’s supplemental GIDs, then the permission bits of that ACL entry are
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checked. If the ACL entry allows the requested access, then access is granted
{AC.4::AC.4.33}. If not, then the next ACL entry is checked until there are no more
entries {AC.4::AC.4.34}.
• If at least one matching ACL entry was found for the GID, or any of the supplemental
GIDs, then processing continues with Step 14 {AC.4::AC.4.35}. If the GID, or any of
the supplemental GIDs, matched the file owner GID, then processing continues with
Step 15 {AC.4::AC.4.36}. Otherwise (neither the GID nor any of the supplemental
GIDs matched either the file owner GID or an ACL entry), processing continues with
the next step {AC.4::AC.4.37}.
• If the requesting user has the RESTRICTED attribute, and the UNIXPRIV class is active
and RACLISTed, and the RESTRICTED.FILESYS.ACCESS resource is protected by a
profile in the UNIXPRIV class, and the user does not have at least READ access, then
go to Step 15 {AC.4::AC.4.38}.
• The file’s “other” permission bits are checked. If the “other” bits allow the requested
access, then access is granted {AC.4::AC.4.39}. Otherwise, go to Step 15.
• If the UNIXPRIV class is active and RACLISTed, and if the
SUPERUSER.FILESYS.ACLOVERRIDE resource is protected by a profile in the UNIXPRIV
class, then the user must have the correct access level as documented for the
ck_access (IRRSKA00) callable service in z/OS Security Server RACF Callable Services.
If the profile exists, it determines whether file access is granted or denied
{AC.4::AC.4.40}.
• If the UNIXPRIV class is active and RACLISTed, and if the SUPERUSER.FILESYS
resource is protected by a profile in the UNIXPRIV class, then the user must have the
correct access level as documented for the ck_access (IRRSKA00) callable service in
z/OS Security Server RACF Callable Services. If the profile exists, it determines
whether file access is granted or denied {AC.4::AC.4.41}.
Access is denied, if none of the above steps has explicitly granted access {AC.4::AC.4.42}.
Algorithm to check DAC access to UNIX IPC objects
The discretionary access control rules allow access to an IPC object,
 if the user has an effective user ID of zero {AC.4::AC.2.70}
 if the user is the owner or creator of the IPC object and the requested type of access
is allowed by the owner related permission bits {AC.4::AC.2.71}
 if the user is neither the owner or creator of the IPC object but is a member of the IPC
object’s creating group or owning group and the requested type of access is allowed
by the group related permission bits {AC.4::AC.2.72}
 if the user is neither owner nor creator of the IPC object and also is not a member of
the IPC object’s creating group or owning group and the access is allowed by the
other related permission bits {AC.4::AC.2.73}
If none of the above mentioned conditions is satisfied, permission is denied by the
discretionary access control rules for IPC objects {AC.4::AC.2.74}.
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8.1.3.6 DAC for LDAP LDBM objects
Access to LDAP directory entries and attributes is defined by Access Control Lists (ACLs).
Each entry in the directory contains a special set of attribute/value pairs which describe who
is allowed to access information within that entry. Attributes associated with access control
are aclEntry, aclPropagate, aclSource, entryOwner, ownerPropagate, and
ownerSource. The aclEntry and entryOwner attributes appear to be part of the entry, but
may in fact be logically associated with an entry, but physically present in some parent
entry higher in the directory tree. When we talk about an LDAP ACL (Access Control List) we
mean the combination of the entryOwner and aclEntry attribute values. If the user is the
entryowner they have administrator level permissions to the entry. If they are not the
entryOwner then we look to the aclEntry attribute values to determine the access.
The TOE controls access to all directory entry objects based on the following security
attributes:
 Entry Owner Information
o entryOwner: defines the DN(s) of the LDAP user(s) or group(s) considered to
own this entry.
o ownerPropagate: indicates whether to propagate the ownership of the entry to
all descendant entries, until another entry with ownerPropagate is found.
 Access Control Attributes (ACA)
o aclEntry: defines the access control information, which can specify access
permissions (grant, deny) for LDAP users or groups that control access to the
complete entry, specific named attributes in the entry, or all attributes in the
entry that belong to a specific attribute class
aclEntry specifications can also filter the user's access based on various
characteristics such as the bind DN , alternate DNs , pseudo DNs , groups that
the bind/alternate DNs belongs to , IP address of the client connection , time
of day that directory entry was accessed , day of week that directory entry
was accessed , the bind mechanism used , whether or not bind encryption
was used.
o aclPropagate: indicates whether to propagate access control information of
the entry to all descendant entries, until another entry with aclPropagate is
found.
Algorithm to check for DAC access to LDAP LDBM objects
The Access Control List for an LDAP LDBM object (entry DN) is determined in the following
way:
a) If there is a set of explicit access control attributes for the object , then the object’s
Access Control List applies {AC.4::AC.4-R8-LDAP-1}.
b) If there is no explicitly defined set of access control attributes, then traverse the
directory tree upwards until an ancestor node is reached with a set of propagating
access control attributes {AC.4::AC.4-R8-LDAP-2}.
If no such ancestor node is found, the default access rights will apply {AC.4::AC.4-R8-LDAP-
3}. The default access rights are predefined as aclEntry:
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group:CN=ANYBODY:normal:rsc:system:rsc and cannot be changed by the Directory
Administrator {AC.4::AC.4-R8-LDAP-4}.
When determining base access (before filtering), processing stops as soon as access can be
determined {AC.4::AC.4-R12-LDAP-5} based on access evaluation as described below:
• The first check for access is done by comparing the subject’s LDAP user ID (bind DN)
and LDAP groups with the effective entryOwner attribute values. If there is a match
with any of the entryOwner values then the subject has full access to the object
{AC.4::AC.4-R8-LDAP-6}. The LDAP Administrator is additionally considered to have
ownership authority for all objects in the directory tree. If the bind DN is an LDAP
Administrator with the appropriate administrative role authority, full access is first
applied. Then permisions for all aclFilter values matching the LDAP administrator's
bind DN and additional access information are applied prior to the server processing
the ACL check. {AC.4::AC.4-R13-LDAP-7}.
• The subject may be granted different access permissions to an object, from specific
access permissions for the subject’s DN and from group memberships (including the
authenticated and anybody groups). The LDAP server uses the following algorithm to
determine which permissions to grant a DN based on the values in the aclEntry
attribute:
 if there is a specific value for the subject’s DN, the subject gets those
permissions only {AC.4::AC.4-R8-LDAP-8}
 else if there is a cn=this value and the subject’s DN is the distinguished name
(DN) of the object, the subject gets those permissions only {AC.4::AC.4-R8-
LDAP-9}
 else if there are one or more group values that the subject is a member of, the
subject gets the union of the permissions for those groups {AC.4::AC.4-R8-
LDAP-10}
 else if there is a cn=authenticated value and the subject is authenticated to
the directory with an LDAP bind operation, the subject gets those permissions
only {AC.4::AC.4-R8-LDAP-11}
 else if there is a cn=anybody value, the subject gets those permissions only
{AC.4::AC.4-R8-LDAP-12}
 otherwise the subject gets no permissions {AC.4::AC.4-R8-LDAP-13}
Permissions may be add (a) or delete (d) or both at the object level {AC.4::AC.4-R8-LDAP-
17}, or read (r), write (w), search (s), or compare (c) or a combination of these at the
attribute {AC.4::AC.4-R8-LDAP-18} or attribute class {AC.4::AC.4-R8-LDAP-19} level.
Permissions may specify grant or deny for any of the above {AC.4::AC.4-R8-LDAP-23}.
Each of the access permissions is discrete. One permission does not imply another.
{AC.4::AC.4-R8-LDAP-14}
Permissions may be specified for the attribute classes normal, sensitive, critical, restricted,
or system {AC.4::AC.4-R8-LDAP-20}
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Administrator-defined attributes may be specified to be in the normal, sensitive, or critical
attribute classes {AC.4::AC.4-R8-LDAP-21}. The default attribute class for administrator-
defined attributes is normal {AC.4::AC.4-R8-LDAP-22}.
With the support for attribute-level permissions as well as grant/deny support, the order of
evaluation of the separate permissions clauses is important. The access control permissions
clauses are evaluated in a precedence order, not in the order in which they are found in the
ACL entry value {AC.4::AC.4-R8-LDAP-15}. With this support, there are four types of
permissions settings: access-class grant permissions, access-class deny permissions,
attribute-level grant permissions, and attribute-level deny permissions. The precedence for
these types of permissions is as follows (from highest precedence to lowest): {AC.4::AC.4-
R8-LDAP-16}
 attribute-level deny permissions
 attribute-level grant permissions
 access-class deny permissions
 access-class grant permissions
Using this precedence, a deny permission takes precedence over a grant permission (for the
same item specified) while attribute-level permissions take precedence over access-class
permissions.
After a user's base access has been determined, it may be modified by Filter ACL entries.
{AC.4::AC.4-R12-LDAP-24}Filter ACLs can set permissions based on any of the following:
 bind DN
 alternate DNs
 pseudo DNs
 groups that the bind or alternate DNs belong to
 IP address of the client connection
 time of day that directory entry was accessed
 day of week that directory entry was accessed
 the bind mechanism used
 whether or not bind encryption was used
Filters support wildcards. Filters will have the same syntax support as LDAP search filters,
where logical rules can be specified, such as “&” (and), “|” (or), and “!” (not), to name a few
{AC.4::AC.4-R12-LDAP-25}.
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{AC.4::AC.4-R12-LDAP-26} To allow flexibility, the new aclEntry filtering mechanism will also
support three operation values that allow users to specify the way in which filtered ACLs will
take effect:
 replace --the base effective ACL is replaced by the filtered ACLs.
If administrators want a client from a given IP address to only have a specific set of
permissions, they would use replace. (This is similar to what Sun ONE supports.)
 union --the base effective ACL is unioned with the filtered ACLs, resulting in a new
effective ACL. This would be used to expand permissions.
If administrators want a client from a given IP address to have a specific set of
permissions, at a minimum, they would use union.
 intersect --the base effective ACL is intersected with the filtered ACLs. This would be
used to reduce permissions.
If administrators want a client from a given IP address to have a specific set of
permissions, if and only if they already have the permissions, they would use
intersect.
As with the operator precedence described above, filter ACL entries specifying “deny” take
precedence over entries specifying “grant” {AC.4::AC.4-R12-LDAP-27}.
8.1.3.7 Access Control Considerations for the ISPF Client Gateway
The ISPF Client Gateway allows two additional ways for users to execute TSO/E commands
and ISPF functions:
• The administrator can configure the HTTP server to allow the HTTP client to request
invocation of the ISPF Client Gateway control program ISPZINT. In this case, ISPZINT
and any commands it invokes will run with the user ID configured by the
administrator (which may be the client user's identity or an identity specified by the
administrator) {AC.4::AC-R10-ISPF-1}.
Additionally, in Labeled Security Mode the commands will run with the security label of the
HTTP server, which the specified or client identity must have access to {AC.3::AC-R10-ISPF-
2}.
• An existing user session (batch job, UNIX process, etc.) can invoke ISPZINT directly.
In this case, ISPZINT and any comands it invokes will run with the user ID of the
invoking user {AC.4::AC-R10-ISPF-3}.
Additionally, in Labeled Security Mode the commands will run with the security label of the
invoking user session {AC.3::AC-R10-ISPF-4}.
Based on information supplied by its client, ISPZINT will either run a single command or it
will run a command and leave the session active to run subsequent commands. When
leaving the session active for subsequent commands, ISPZINT will ensure that those
commands run with the same user ID as the original command {AC.4::AC-R10-ISPF-5}.
Additionally, in Labeled Security Mode the subsequent commands will run with the same
security label as the original command {AC.3::AC-R10-ISPF-6}.
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8.1.4 Communication security
z/OS provides communications security functions in several system components:
 Communications Server (stack access control, packet filter, IPSec, Application
Transparent TLS),
 System SSL (SSL, TLS)
 Network Authentication Service (Kerberos, GSSAPI)
 NFS client and server (using Kerberos and GSSAPI functions supplied by the Network
Authentication Service)
 IBM Ported Tools for z/OS (OpenSSH)
8.1.4.1 Communications Server
z/OS provides basic networking functions with the Communications Server component. This
subsystem provides support for network communication using the IBM SNA protocols as well
as the TCP/IP protocol suite. APIs for both protocol stacks are provided. For IP, both IPv4 and
IPv6 are supported.
The Communications Server uses RACF to protect access of users to the following resources:
 the TCP/IP stack in general {CS.1::CS.1.1}
 TCP and UDP ports {CS.1::CS.1.2}
 IP addresses {CS.1::CS.1.3}
 Centralized policy information for QoS (Qualities of Service), PBR (Policy-Based
Routing), IPSec, IDS (Intrusion Detection Services), and AT-TLS policy {CS.1::CS.1-R9-
CS-POLCEN-1}.
 Network management information related to IP Filters and IPSec security associations
{CS.1::CS.1-R9-CS-SECMON-1}
 Network Security Services, which provides centralized services for clients allowing:
o IKE daemons to perform RSA and ECDSA signature generation and verification as
well as RSA and ECDSA certificate management/validation functions (ECDSA is only
supported with IKEv2) through the System SSL gsk_validate_certificate_mode
API{CS.1::CS.1-R12-CS-NSS-5} and through additional certificate revocation
checking. {CS.1::CS.1-R13-CS-NSS-6}
o XMLAppliance clients to perform remote RACF authentication and access control
functions {CS.1::CS.1-R10-CS-NSS-1}, certificate management functions {CS.1::CS.1-
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R11-CS-NSS-2}, private key retrieval {CS.1::CS.1-R11-CS-NSS-3}, and RSA signature
creation and RSA decryption {CS.1::CS.1-R11-CS-NSS-4}.
z/OS provides the following security functions as part of the Communications Server:
 Access Control for the IP stack and access control to ports and port ranges:
The IP stack as well as TCP/UDP ports and port ranges can be protected with RACF.
Users can be granted or denied access to the IP stack in general as well as to
individual ports and port ranges. See TCP/IP connections for the associated security
claims.
 z/OS Communications Server provides packet filtering functionality that can control
information flow into or out of the system based on security characteristics of the
packets or of the network interface they use.
 IPSec security associations:
The Communications Server can be configured to establish IPSec security
associations at the IP layer. All packets transmitted between security association
endpoints will be authenticated, encrypted, or both using the configured algorithms.
The Communications Server provides support for IPSec-protected communication in
accordance with RFCs 4301 through 4305, 4308, and 4835 {CS.1::CS.1-R12-IPSec-1}
and IKEv2 in accordance with RFCs 5996, 4307 through 4308, 4718, 4753, 4754,
4809, 4868, 4869 and 4945 {CS.1::CS.1-R13-IPsec-6}. It also provides the IKE
application that negotiates IPSec security association parameters with
communication peers {CS.1::CS.1-R8-IPSec-2}. IPSec is configured through the
PROFILE.TCPIP configuration and the Policy Agent (see section Network configuration
and management).
IPSec, when authenticating using certificates, will obtain the subject alternate
extension present in the client's certificate and compare it contents to the identity
defined in the IKE security policy {CS.1::CS.1-R12-IPSec-7}.
 A Network Security Services (NSS) server that can be used by:
o IKE daemons to perform RSA signature generation and verification and
certificate management/validation from a centralized location, minimizing the
number of systems on which digital certificates for the IKE daemons must be
installed t
o Network management applications to monitor and manage IPSec on NSS
client nodes (see the Network Management section)
o XMLAppliance applications to remotely perform RACF user authentication and
access control calls for RACF resources that the application specifies, as well
as certificate management operations, retrieval of private keys from RACF
certificates, and RSA signature generation and RSA decryption using ICSF-
protected keys.
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The Network Security Server will authenticate its clients using the RACF user ID and
password or PassTicket that they provide and will ensure that the connection is
protected by AT-TLS {IA.1::IA-R9-CS-NSS-1}.
For the IKE certificate-based processing, the Network Security Server will authorize
use of its services via resources in the SERVAUTH class:
o EZB.NSS.sysname.clientname.IPSEC.CERT to control whether the client can
request certificate services {AC.4::AC-R9-CS-NSS-1}
o EZB.NSSCERT.sysname.mappedlabelname.CERTAUTH to control whether the
client can access a CERTAUTH certificate on the NSS server’s key ring
{AC.4::AC-R9-CS-NSS-2}.
o EZB.NSSCERT.sysname.mappedlabelname.HOST to control whether the client
can access a personal or SITE certificate on the NSS server’s key ring
{AC.4::AC-R9-CS-NSS-3}.
For the XMLAppliance certificate processing, the Network Security Server will
authorize use of certificates and private keys via resources in the SERVAUTH class:
 EZB.NSSCERT.sysname.mappedlabelname.CERTAUTH or
EZB.NSSCERT.sysname.mappedlabelname.HOST to control whether the client
can access a certificate on the NSS server's keyring.{AC.4::AC-R11-CS-NSS-9}
 EZB.NSSCERT.sysname.mappedlabelname.PRIVKEY to control whether the
client can access a private key, either through direct retrieval or for usage in
RSA signature generation or RSA decryption.{AC.4::AC-R11-CS-NSS-10}
The Network Security Server will authorize use of the network management service
via the EZB.NSS.sysname.clientname.IPSEC.NETMGMT resource in the SERVAUTH
class. NSS IPSec clients that a connect with a user ID permitted to this resource are
allowed to utilize the IPSec monitoring and management service provided by the NSS
server {AC.4::AC-R12-CS-NSS-4}.
The Network Security Server will authorize the use of XMLAppliance services as
follows:
 RACF user authentication and access control calls require READ access to the
EZB.NSS.sysname.clientname.XMLAPPLIANCE.SAFACCESS resource in the
SERVAUTH class. {AC.4::AC-R10-CS-NSS-5}.
 Certificate management calls require READ access to the
EZB.NSS.sysname.clientname.XMLAPPLIANCE.CERT resource in the SERVAUTH
class {AC.4::AC-R11-CS-NSS-6}
 Private key retrieval calls require READ access to the
EZB.NSS.sysname.clientname.XMLAPPLIANCE.PRIVKEY resource in the
SERVAUTH class {AC.4::AC-R11-CS-NSS-7}
 RSA signature generation and RSA decryption calls from XMLAppliance clients
require READ access to the
EZB.NSS.sysname.clientname.XMLAPPLIANCE.PRIVKEY resource in the
SERVAUTH class {AC.4::AC-R11-CS-NSS-8}
 SSL / TLS layer to set up a trusted channel to another trusted IT product, in a way
transparent to the application (called Application Transparent TLS, or AT-TLS). The
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selectable algorithms can be limited by configuring a subset of allowable algorithms
at the server. The SSL/TLS protocol can be used to set up a trusted channel to
another system through a potentially insecure network. SSL/TLS protects the data
against disclosure and attacks related to integrity like undetectable modifications or
replay. Servers can support encryption using TDES with 168-bit key length or AES
with either 128- or 256-bit key length. Application Transparent Transport Layer
Security (AT-TLS) supports the use of all cipher suites supported by System SSL
{CS.1::CS.1.4-R13}. The TN3270 and FTP protocols are enabled to use AT-TLS and
can be tunneled through SSL/TLS to establish a trusted channel to another trusted IT
product that also implements this protocol {CS.1::CS.1.5}. Applications that AT-TLS
has been configured to support, can be tunneled through SSL/TLS to establish a
trusted channel to another trusted IT product that also implements this protocol
{CS.1::CS.1-V1R7.1}.
o An rpcbind application with the following characteristics:
o Control over which users can register or deregister application port
information, which prevents unauthorized users from directing application RPC
requests to the wrong TCP/IP port. To implement this security control,
administrators define a RACF SERVAUTH profile to protect
EZB.RPCBIND.<system-name>.<rpc-bind-name>.REGISTRY and give
appropriate users READ access. This control protects the registerrpc(),
svc_register(), pmap_set(), and pmap_unset() services {CS.1::CS.1-R10-CS-1}.
In a multilevel secure environment no application can register or deregister
with rpcbind unless this profile exists and grants access {CS.1::CS.1-R10-CS-
2}.
o When operating in a multilevel secure environment, the rpcbind target
assistance functions will assume the SECLABEL of the requesting process
before forwarding the request to the target server. This will ensure that the
target server knows the proper SECLABEL for the data it receives {CS.1::CS.1-
R10-CS-3}.
AT-TLS is configured through the PROFILE.TCPIP configuration file and the Policy Agent. This
configuration may also specify a list of LDAP servers for certificate revocation information
(see Section Network configuration and management).
Note: When hardware crypto has been activated, the cryptographic operations performed
by IPSec {CS.1::CS.1-R8-IPSec-3} and System SSL {CS.1::CS.1-R8-SSL-1} will make use of
the hardware crypto when appropriate, either through ICSF or the CPACF processor
instructions. In the absence of hardware crypto support, IPSec {CS.1::CS.1-R9-IPSec-4} and
System SSL {CS.1::CS.1-R9-SSL-2} will use software algorithms for cryptographic
operations, although in the case of AES (CBC, GCM, and GMAC) encryption and SHA-2
digests IPSec will still make use of ICSF {CS.1::CS.1-R13-IPSec-5}. For symmetric (TDES,
AES) and hashing (SHA-1, SHA-2) functions, ICSF will invoke the CPACF if it supports the
function or will provide the functions via software within ICSF {CS.1::CS.1-R13-ICSF-1}.
Packet filtering functionality that can control information flow into or out of the system
based on security characteristics of the packets or of the network interface they use, as
follows:
o {CS.1::CS.1-R12-PF-1} Filter rules can apply to a packet based on information
within the packet or information external to the packet.
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 Internal information: source address, destination address, protocol,
source port, or destination port, ICMP type and code, OSPF type, and
mobility header type.
 External information: the direction of packet flow routing attribute,
security class (determined by the network interface used by the
packet).
o {CS.1::CS.1-R12-PF-2} When a filter rule applies to a packet, it can discard the
packet silently, discard the packet with ICMP notification to the sender,
permit the packet flow, or permit the packet flow and enforce IPSec
processing.
o {CS.1::CS.1-R11-PF-3} A z/OS TCP/IP stack configured for IP security
implements a default “deny” policy in the absence of any configured filter
rules.
In addition, the Communications Server provides the following application protocols that
include user authentication using RACF:
 FTP (user authentication is optional) {CS.1::CS.1.6}
 telnet {CS.1::CS.1.7}
 rlogin, rsh, and rexec {CS.1::CS.1.8}
 TN3270 {CS.1::CS.1.9}
 Network Security Services Server {CS.1::CS.1-R10-NSS-6}
 Policy Agent Server {CS.1::CS.1-R10-CS-POLCEN-12}
 Load Balancing Advisor {CS.1::CS.1-R10-CS-LBA-3}
z/OS also provides an HTTP server that uses RACF for authentication, (though the
administrator can also configure anonymous access if necessary) {CS.1::CS.1.V1R7.2}
Access control to resources used within a FTP, HTTP, or telnet session is also performed
using RACF {CS.1::CS.1.10}.
Import of certificates and key pairs used for authentication and key exchange for the
SSL/TLS and IPSec protocols is restricted to authorized administrators {CS.1::CS.1.11}.
The FTP and TN3270 Server applications can use AT-TLS services to provide end-to-end data
channels that are authenticated and encrypted {CS.1::CS.1-R8-CS-1}. AT-TLS (Application
Transparent Transport Layer Security) uses System SSL services to provide end-to-end data
channels that are authenticated and encrypted for most TCP applications.
8.1.4.2 System SSL
z/OS provides SSL/TLS functions via the System SSL component for applications wishing to
use SSL/TLS directly (without taking advantage of the AT-TLS functions of the
Communications Server). The selectable algorithms can be limited by configuring a subset of
allowable algorithms at the server {CS.2::CS.1-R8-SSL-2}. The SSL/TLS protocol can be used
to set up a trusted channel to another system through a potentially insecure network.
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SSL/TLS protects the data against disclosure and attacks related to integrity like
undetectable modifications or replay. Servers can support encryption using TDES with 168-
bit key length {CS.2::CS.1-R8-SSL-3}, AES with either 128- or 256-bit key length
{CS.2::CS.1-R8-SSL-4} utilizing session keys generated with information provided through
an RSA key exchange method. These same encryption types can utilize session keys
generated with information provided through an EC Diffie-Hellman key exchange
{CS.2::CS.1-R13-SSL-6} .
8.1.4.3 Network Authentication Service
The z/OS Network Authentication Service provides communication security via the Kerberos
and GSS-API protocols, which use one of the supported encryption protocols (TDES, AES-128,
AES-256) to encrypt application messages when requested by applications that support
Kerberos and GSS-API functions {CS.3::CS.1-R13-KERB-1}.
The z/OS Network Authentication Service will utilize ICSF to drive encryption requests to
CPACF for DES, TDES, AES-128, and AES-256).{CS.3::CS.1-R13-KERB-2}
If requested by the applications using the appropriate AP_REQ extension the z/OS Network
Authentication Service will allow the applications to negotiate and agree upon encryption
types not understood by the KDC {CS.3::CS.1-R13-KERB-3}.
8.1.4.4 NFS Client and Server
The z/OS NFS client and server support the use of Kerberos (via the Network Authentication
Service) to provide integrity and confidentiality for authentication credentials and data as
they flow over the network. NFS server configuration parameters allow the administrator to
configure use of Kerberos for network traffic and the z/OS NFS client and server support the
following Kerberos V5 security mechanisms {CS.4::CS.1-R10-NFS-1}:
 krb5, which provides Kerberos V5 based integrity on the RPC credentials (but not
data) using the DES_MAC_MD5 integrity algorithm and uses the RPCSEC_GSS service
of rpc_gss_svc_none.
 krb5i, which provides Kerberos V5 based integrity on both the RPC credentials and
data using the DES_MAC_MD5 integrity algorithm and uses the RPCSEC_GSS service
of rpc_gss_svc_integrity.
 krb5p, which provides Kerberos V5 based integrity and privacy on both the RPC
credentials and data using the DES_MAC_MD5 algorithm for integrity and 56 bit DES
for privacy. It uses the RPCSEC_GSS service of rpc_gss_svc_privacy.
When acquiring Kerberos tickets the z/OS NFS client supports the following encryption
options {CS.4::CS-1-R10-NFS-5}:
 ENCTYPE_DES_CBC_MD5
8.1.4.5 IBM Ported Tools for z/OS (OpenSSH)
Additionally, the IBM Ported Tools for z/OS provide OpenSSH functionality, with an sshd
daemon that supports the SSHv2 protocol {CS.5::CS.1-R8-SSH-1} and these commands to
allow remote users to perform work on the z/OS system:
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 ssh, to establish a UNIX shell environment {CS.5::CS.1-R8-SSH-2}
 scp to perform remote file copying operations {CS.5::CS.1-R8-SSH-3}
 sftp to perform file transfer operations (similar to ftp) {CS.5::CS.1-R8-SSH-4}
 ssh-keygen to generate the host key files and the RSA or DSA key pairs {CS.5::CS.1-
R8-SSH-7}
The SSH protocol can be used to set up a trusted channel to another system through a
potentially insecure network. SSH protects the data against disclosure and attacks related to
integrity like undetectable modifications or replay. SSH supports encryption using TDES with
168-bit key length {CS.5::CS.1-R8-SSH-5} and AES with 128-, 192-, or 256-bit key length
{CS.5::CS.1-R8-SSH-6}, {CS.5::CS.1-R9-OpenSSH-1}.
8.1.5 Management
8.1.5.1 User and group management
Definition of users and groups
z/OS users and groups are defined in RACF.
LDAP LDBM users and groups are defined in the LDAP server, but the LDAP users must be
mapped one-to-one to RACF z/OS users. See LDAP LDBM Users for info on defining LDAP
users.
Local Kerberos users are defined as z/OS users who also have a KERB segment in their RACF
USER profile. A remote (foreign) Kerberos user may be defined locally by mapping the
foreign principal name to a local z/OS (RACF) user via KERBLINK profiles. See Defining
Kerberos Users for more discussion of this topic.
To create a z/OS user, a user profile for the new user has to be created in RACF. Each user
profile consists of a base segment and optional segments for the use of specific subsystems.
In the evaluated configuration, the base segment, the KERB segment, and the OMVS
segment for the specification of attributes for z/OS UNIX System Services contain the
information required by the security functions defined in this Security Target. Other
segments of the user profile may exist but the effects of any values in those segments do
not influence the security policy defined in this Security Target. RACF also supports a special
user profile segment, CSDATA, for which the security administrator can specify the format
and content of the data fields using other profiles in the CFIELD class, as well as specifying
access rules in the FIELD class to determine which users can view or update data in the
segment {SM.1::SM.1-R10-RACF-19}.
To create or modify a user profile, a user must have one of the following authorities:
 the SPECIAL role as a general system administrator {SM.1::SM.1.1}
 the UPDATE authority to the fields in a non-base segment of the profile he wants to
modify through field-level access checking {SM.1::SM.1.2}
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 to create a new user: is connected to a group that has the group-SPECIAL role and
has the CLAUTH attribute for the USER class and is the owner of or has JOIN authority
in the new user’s default group. Note that the following roles of the ADDUSER
command can not be assigned in this case: OPERATIONS, SPECIAL, and AUDITOR
{SM.1::SM.1.3}
 to modify the attribute of a user: the CLAUTH attribute for the user class
{SM.1::SM.1.4}. Note that only the CLAUTH and NOCLAUTH attribute can be changed
{SM.1::SM.1.5}.
To list the contents of a user (user-2) profile using the LISTUSER command, a user (user-1)
must have one of the following authorities:
 The SPECIAL role as a general system administrator, or the group-SPECIAL role as a
group-administrator for user-2, the AUDITOR role, the group-AUDITOR role as a group
auditor for user-2, or user-1 must own user-2 {SM.1::SM.1-R10-RACF-1}
 READ authority to the fields in a non-base segment of the profile he wants to list
through field-level access checking {SM.1::SM.1-R10-RACF-2}
 When user-2 does not have the SPECIAL, OPERATIONS, or AUDITOR roles:
o READ authority to FACILITY resource IRR.LISTUSER {SM.1::SM.1-R10-RACF-3}
o READ authority to FACILITY resource IRR.LU.OWNER.owner-of-profile to allow
use of LISTUSER for any non-excluded user-2 owned by “owner-of-profile”
(which specifies a user ID or group name). {SM.1::SM.1-R10-RACF-4}
o READ authority to FACILITY resource IRR.LU.TREE.owner-of-tree to allow use of
LISTUSER for any non-excluded user-2 who would be in the group-SPECIAL
scope of “owner-of-tree” (which specifies a user ID or group name). That is,
users owned by “owner-of-tree” or owned by groups owned by “owner-of-
tree” {SM.1::SM.1-R10-RACF-21}
o To exclude a user-2 from being listed using IRR.LU.OWNER.owner-of-profile or
IRR.LU.TREE.owner-of-tree authority, the administrator can define a profile
that protects the resource IRR.LU.EXCLUDE.excluded-user-2 in the FACILITY
class. With such a profile defined, a user also needs READ authority to it in
order to gain authority via IRR.LU.OWNER.owner-of-profile or
IRR.LU.TREE.owner-of-tree {SM.1::SM.1-R10-RACF-5}.
To reset the password for another user to an expired value using the PASSWORD or PHRASE
commands:
 The SPECIAL role as a general system administrator, the group-SPECIAL role as a
group-administrator for user-2 ,or user-1 must own user-2 {SM.1::SM.1-R10-RACF-6}.
To reset the password or password phrase for another user (user-2) or to resume user-2
using the ALTUSER command, a user (user-1) must have one of the following authorities:
 To specify a new expired or non-expired password/phrase, the SPECIAL role as a
general system administrator {SM.1::SM.1-R10-RACF-7}
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 To specify a new expired password/phrase, the group-SPECIAL role as a group-
administrator for user-2 ,or user-1 must own user-2 {SM.1::SM.1-R10-RACF-8}
 When user-2 does not have the SPECIAL, OPERATIONS, or AUDITOR roles, or the
PROTECTED attribute, one of:
o READ authority to FACILITY resource IRR.PASSWORD.RESET to specify a new
expired password/phrase when not within the minimum change window for
user-2, or resume user-2 without specifying a resume date. User-1 can not set
a phrase for a user-2 who does not have one already {SM.1::SM.1-R10-RACF-
9}
o UPDATE authority to FACILITY resource IRR.PASSWORD.RESET to specify a
new non-expired password/phrase when not within the minimum change
window for user-2, or resume user-2 without specifying a resume date. User-1
can not set a phrase for a user-2 who does not have one already {SM.1::SM.1-
R10-RACF-10}.
o CONTROL authority allows the same as UPDATE, but also allows changing the
password/phrase even when within the minimum change window for user-2
{SM.1::SM.1-R10-RACF-11}.
o READ authority to FACILITY resource IRR.PWRESET.OWNER.owner-of-profile to
specify a new expired password/phrase or resume a user without specifying a
resume date, for any non-excluded user-2 owned by “owner-of-profile” (which
specifies a user ID or group name) {SM.1::SM.1-R10-RACF-12}
o UPDATE authority allows the same as READ, and also allows setting a non-
expired password or password phrase {SM.1::SM.1-R10-RACF-13}.
o CONTROL authority allows the same as UPDATE, and also allows setting a new
password/phrase even when within the minimum change window for user-2
{SM.1::SM.1-R10-RACF-14}.
o READ authority to FACILITY resource IRR.PWRESET.TREE.owner-of-tree to
specify a new expired password/phrase or resume a user without specifying a
resume date, for any non-excluded user-2 who would be in the group-SPECIAL
scope of “owner-of-tree” (which specifies a user ID or group name). That is,
users owned by “owner-of-tree” or owned by groups owned by “owner-of-
tree” {SM.1::SM.1-R10-RACF-15}.
o UPDATE authority allows the same as READ, and also allows setting a non-
expired password or password phrase {SM.1::SM.1-R10-RACF-16}.
o CONTROL authority allows the same as UPDATE, and also allows setting a new
password/phrase even when within the minimum change window for user-2
{SM.1::SM.1-R10-RACF-17}.
o To exclude a user-2 from being altered using IRR.PWRESET.OWNER.owner-of-
profile or IRR.PWRESET.TREE.owner-of-tree authority, the administrator can
define a profile that protects the resource IRR.PWRESET.EXCLUDE.excluded-
user-2 in the FACILITY class. With such a profile defined, a user also needs
READ authority to it in order to gain authority via
IRR.PWRESET.OWNER.owner-of-profile or IRR.PWRESET.TREE.owner-of-tree
{SM.1::SM.1-R10-RACF-18}
RACF allows groups of users to be defined, making the management of users and user
attributes and roles easier. To create a new group, a group profile must be defined in RACF.
A group profile (as a user profile) consists of a base segment and (optional) other segments.
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As with the user profiles all group attributes related to the Security Policy as defined in this
Security Target are contained in the base segment and the OMVS segment of the group
profile. Each group defined in RACF must be owned by a RACF-defined user or by its superior
group. Ownership of a group is assigned with the ADDGROUP command when a new group
profile is created and can be changed with the ALTGROUP command used to change an
existing group profile {SM.1::SM.1.6}.
RACF also supports a special group profile segment, CSDATA, for which the security
administrator can specify the format and content of the data fields using other profiles in the
CFIELD class, as well as specifying access rules in the FIELD class to determine which users
can view or update data in the segment {SM.1::SM.1-R10-RACF-20}.
The owner of a group or a user connected to a group that has the group-SPECIAL role can:
 Define new users to RACF (provided he also has the CLAUTH attribute for the USER
class) {SM.1::SM.1.7}.
 Connect and remove users from the group {SM.1::SM.1.8}.
 Delegate and change group authorities and set the default UACC for all new
resources belonging to members of the group {SM.1::SM.1.9}.
 Modify, list, and delete the group profile {SM.1::SM.1.10}.
 Define, delete, and list the names of the subgroups under the group
{SM.1::SM.1.11}.
 Specify the group terminal option {SM.1::SM.1.12}.
Users can be connected to a number of groups and have the group-related authorities of all
the groups they are connected to {SM.1::SM.1.13}.
The OMVS segment of a group profile contains the group’s z/OS UNIX group identifier.
Management of z/OS user and group profiles occurs primarily via the RACF commands
described later (ADDUSER, ALTUSER, DELUSER, LISTUSER, ADDGROUP, ALTGROUP,
DELGROUP, LISTGRP). Administrators enter these commands while running in a TSO session.
Additionally, for administrative convenience, the z/OS LDAP server and RACF provide an
administrative back-end to LDAP known as SDBM. RACF administrators can authenticate to
LDAP using a RACF identity and password or using a digital certificates over SSL/TLS (LDAP
SASL bind with EXTERNAL verification) mapped to a RACF USER ID, then make requests to
the SDBM back-end via LDAP programming protocols. These requests allow the
administrator to view or update RACF USER, GROUP, CONNECT and general resource profile
information, and SETROPTS class-related options. LDAP transforms those requests into a
tagged format supported by the R_admin() callable service, and uses that service to pass
them to RACF for processing, just as though they were entered via TSO. Because the LDAP
mechanisms merely provide a transformation of the administrator’s LDAP request into a
different format (RACF command structure), and RACF performs the authentication, and all
security checking and administrative actions occur within RACF just as for the TSO
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commands, we do not view this LDAP mechanism as relevant to security. Therefore we do
not address it further in this document.
The TOE also provides an interface via Java classes and methods that allows Java programs
to perform RACF user and group administration in a manner similar to that used for the
LDAP SDBM back-end processing. The Java program invokes the provided Java methods,
which transform the provided data into RACF commands and issues them via R_admin().
RACF then processes the commands as though they were entered via TSO, using the
identity of the user running the Java program {SM.1::SM.1-R9-JSEC-1}.
User profiles
The base segment of a user profile within RACF contains (among other data not relevant for
the security functions defined in this Security Target) the following:
Name Description
USERID User’s identification (a maximum of 8 characters).
NAME User’s name (not security relevant, because the user is allowed to change
his name).
OWNER Owner of the user’s profile.
DFLTGRP User’s default group. (Note: A user may specify, at login time, any group he
or she is connected to as the current default group. This does not change
the DFLTGRP value in the profile.)
AUTHORITY User’s authority in the default group (use, create, connect, join).
PASSWORD User’s password. The user ID is DES-encrypted using the password (padded
with blanks) as a key. Users who have no password and no password
phrase are said to have the PROTECTED attribute, and can not logon to the
system via any mechanism that uses a password, password phrase, or
PassTicket.
PHRASE Optional password phrase. Users who have a phrase must also have a
password.
REVOKE This attribute consists of a flag and a date. The date parameter specifies the
date on which the user is revoked. The flag indicates that the user is
revoked. The user is revoked, if either the flag is set or the actual date is
after the revoke date, if defined.
RESUME Date on which RACF lets the user have access to the system again.
UACC Default universal access authority for resource profiles that the user
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Name Description
defines. Only applicable to DATASET and a few general resource classes).
WHEN Days of the week and hours of the day during which the user has access to
the system (applies only to login through a terminal, not to other ports-of-
entry).
CLAUTH Classes in which the user can define profiles.
SPECIAL Gives the user the system-wide SPECIAL attribute.
AUDITOR Gives the user the system-wide AUDITOR attribute.
OPERATIONS Gives the user the system-wide OPERATIONS attribute.
MODEL Name of the data set model profile to be used when creating new data set
profiles, either generic or discrete.
SECLABEL User’s default security label (evaluated in Labeled Security Mode only).
CERTNAME The names of the profiles in the DIGTCERT (digital certificate) class that are
related this RACF user ID.
CERTLABL The certificate labels associated with the profiles in the DIGTCERT class that
are related to this RACF user ID.
The OMVS segment in a user profile contains the following fields (among other information
not relevant for the security policy as defined in this Security Target:
HOME
User’s z/OS UNIX initial directory path name
PROGRAM
User’s z/OS UNIX program path name, such as a default shell program
UID
User’s z/OS UNIX user identifier
Administrators have several choices when establishing OMVS information for users:
• They may define the OMVS segment for users completely manually, via ADDUSER or
ALTUSER with the OMVS keyword, and explicit specifications for the value of HOME,
PROGRAM, and UID {SM.1::SM.1-R11-RACF-1}.
• They may define the OMVS segment via ADDUSER or ALTUSER with the OMVS
keyword and explicit specifications for HOME and PROGRAM, but allowing RACF to
automatically choose the UID via the AUTOUID keyword , in conjunction with the
BPX.NEXT.USER profile in the FACILITY class, where the administrator specifies an
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APPLDATA field containing the allowable range of automatically-assigned UIDs. RACF
will then assign the lowest available unique UID and update the APPLDATA
information to indicate the UID it used {SM.1::SM.1-R11-RACF-2}.
• They may define the OMVS information implicitly, through use of the
BPX.DEFAULT.USER profile in the FACILITY class. With the profile, the APPLDATA
specifies the RACF user ID of a user who has an OMVS segment, and when a user
without an OMVS segment needs to run a UNIX process, the system will temporarily
use the HOME, PROGRAM, and UID information from the user named in
BPX.DEFAULT.USER {SM.1::SM.1-R11-RACF-3}.
• They may define the OMVS information automatically, by specifying the
BPX.NEXT.USER profile in the FACILITY class to record the allowable range of
automatically-assigned UIDs (as above), and the BPX.UNIQUE.USER profile to indicate
that whenever a user without an OMVS segment makes use of UNIX functions, RACF
should automatically create a permanent OMVS segment for the user, with a unique
UID and with HOME and PROGRAM information derived from the user named in
BPX.DEFAULT.USER {SM.1::SM.1-R11-RACF-4}. This process will also occur if
someone inquires about the UID for a user who does not have one using the
getumap() callable service. {SM.1::SM.1-R11-RACF-10}
The KERB segment in a user profile contains the following fields:
ENCRYPT
Encryption methods allowable for this user: DES, DES3 (TDES), DES with key
derivation, AES128, or AES256. For this evaluation only DES3, AES128, or AES256 is
allowable.
KERBNAME
The Keberos principal ID for a locally-defined Kerberos user.
MAXTKTLFE
The maximum lifetime of a Kerberos ticket for this user.
Defining Kerberos Users
z/OS recognizes two kinds of Kerberos users: local and foreign. To define a local Kerberos
user, add a KERB segment to the USER profile. Specify the encryption type as DES3 (TDES),
NODES, NODESD NOAES128 NOAES256 to ensure that TDES encryption processing is used
for this user. Specify the encryption type as AES128 AES256 NODES3 NODES NODESD to
ensure use of AES encryption for this user. Specify the user’s Kerberos principal name. When
the user next changes his/her password/phrase, the user’s encryption keys will be generated
from the new RACF password/phrase {SM.1::SM.1-R10-KERB-1}.
To allow a foreign Kerberos user to authenticate, define a trust relationship between the
local Kerberos realm and the foreign realm, using either the peer or transitive trust methods,
by defining REALM profiles with passwords in RACF as described in the Network
Authentication Service Administration guide {SM.1::SM.1-R8-KERB-2}. Kerberos passwords
up to 128 characters in length may be specified in the REALM profiles {SM.1::SM.1-R10-
KERB-4}. Then, for each foreign principal you want to accept, define a KERBLINK profile in
RACF specifying the name of the local user in the APPLDATA field, as described in the RACF
Security Administrator’s Guide {SM.1::SM.1-R8-KERB-3}.
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LDAP LDBM Users
LDAP has the ability to authenticate to RACF through LDBM by supplying a RACF
password/phrase on a simple bind to the LDBM back-end or by a digital certificates over
SSL/TLS (LDAP SASL bind with EXTERNAL verification) mapped to a RACF USER ID.
Authorization information is still gathered by the LDAP server back-end based on the DN that
performed the bind operation. The LDAP administrator defines the authorized LDAP LDBM
users by defining “subject distinguished names” DNs in the LDBM directory. Additionally, for
the evaluated configuration, the administrator must define the DN as using what LDAP calls
native authentication (i.e, RACF authentication) rather than LDAP authentication, and must
provide the RACF user ID that represents this LDAP subject. During the bind operation, the
client user will provide his/her subject DN and the RACF password for the RACF user ID that
corresponds to that subject DN. The LDAP server will then use z/OS authentication functions
to validate the specified password against the configured RACF user ID. (Note: Security
claims appear earlier under Identification and Authentication functions.)
Digital Certificates, Key Rings, and Certificate Mappings in RACF and
PKCS#11 Cryptographic Tokens
RACF provides the RACDCERT command which can be used to
• create certificate requests to send to a Certifying Authority {SM.1::SM.1-R8-RACF-
RACDCERT-1}
• generate public/private key pairs and certificates (DIGTCERT class) {SM.1::SM.1-R8-
RACF-RACDCERT-2}
• export a certificate or certificate packages to a data set, optionally with the private
key {SM.1::SM.1-R8-RACF-RACDCERT-3}
• install certificates into the RACF database and register them as belonging to a user or
to a certifying authority {SM.1::SM.1-R8-RACF-RACDCERT-4}. The __certificate() and
InitACEE() services can also register/deregister certificates {SM.1::SM.1-R8-RACF-
RACDCERT-5}, and administrators an allow users to register their own certificates by
granting them READ access to FACILITY resource IRR.DIGTCERT.ADD {SM.1::SM.1-R8-
RACF-RACDCERT-6}.
• delete or list certificates in the RACF database {SM.1::SM.1-R8-RACF-RACDCERT-7}
• maintain (create, list, delete) key rings containing certificates (DIGTRING class)
{SM.1::SM.1-R8-RACF-RACDCERT-8}
• add certificates to or delete them from key rings {SM.1::SM.1-R8-RACF-RACDCERT-9}
• create mapping rules (certificate name filters) that can map client certificates that
are not installed/registered in the database to specified user IDs based on subject or
issuer information (DIGTNMAP class) {SM.1::SM.1-R8-RACF-RACDCERT-10}. This can
allow a many-to-one mapping for applications that do not need to have each user run
under his own ID. In this case, accountability can be maintained for auditing purposes
by having the application provide the subject’s distinguished name via the
X500Name parameter when creating the security environment (ACEE) for the user
{SM.1::SM.1-R8-RACF-RACDCERT-11}. The mapping process can also make use of
mapping criteria specified by the DIGTCRIT class when it is necessary to map a client
certificate into different IDs depending on characteristics of the user’s session (such
as the application name, or system name where the application is running)
{SM.1::SM.1-R8-RACF-RACDCERT-12}.
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• create and manage the contents of PKCS#11 cryptographic tokens contained in the
ICSF TKDS {SM.1::SM-1.R9-RACF-RACDCERT-13}
{SM.1::SM-1.R12-RACF-RACDCERT-14} RACDCERT supports installing or
generatingcertificates that have the following key characteristics, subject to US
export regulations and the available cryptographic hardware present on the system:
◦ RSA keys up to 4096 bits
◦ DSA keys up to 1024 bits;
◦ NIST ECC keys up to 521 bits;
◦ Brainpool ECC keys up to 512 bits (non-twisted curves only).
{SM.1::SM-1.R13-RACF-RACDCERT-15} RSA keys can be generated through
• RACF software and stored in the RACF DB (clear key)
• RACF software and stored in the ICSF PKDS (clear key)
• Cryptographic cards and stored in the ICSF PKDS (secure key)
{SM1.::SM-1.R13-RACF-RACDCERT-16} NIST/Brainpool keys can be generated through
• ICSF software and stored in the RACF database (clear key)
• CryptoExpress3 coprocessor cards (z114 or z196 processor) and stored in the
ICSF PKDS (secure key)
z/OS also provides the PKI Services component which provides a full-function Certificate
Authority and certificate life-cycle management process. Certificates that PKI Services
issues are not (by default) placed in the RACF database, but may be put there manually by
users or administrators. See PKI Services for additional details.
The rest of this section describes processing in RACF.
Profiles in the DIGTCERT class contain information about digital certificates contained in the
RACF database, as well as the certificate itself and optionally the certificate’s private key.
Additionally, the user’s USER profile will have information about a certificate associated with
the user.
Profiles in the DIGTRING class contain information about key rings and the certificates
contained in a key ring. Each key ring is a named collection of the personal, site, and CA
certificates associated with a user. When the user represents a server, the key ring has the
allowable CA certificates that must be used to sign certificates presented by clients of the
server during SSL handshaking.
Profiles in the DIGTNMAP and DIGTCRIT classes contain profiles used during certificate name
filtering, a process during client authentication that can derive a user ID to use for the
session from a certificate that is not specifically registered in the RACF database.
Note that only the RACDCERT command may be used to administer profiles in the
DIGTCERT, DIGTRING, and DIGTNMAP classes.
Management for RACF Digital Certificates, Key Rings, Certificate
Mappings, and Criteria
Administrators can use the RACDCERT command to generate or delete digital certificates,
generate certificate requests, maintain key rings, and maintain certificate mappings. RACF
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maintains certificates in the DIGTCERT class, key rings in the DIGTRING class, and certificate
mappings in the DIGTNMAP class.
Additionally RACF provides programming interfaces to allow applications to maintain RACF
key rings.
Management for RACF digital certificates, key rings, certificate mappings, and certificate
mapping criteria occurs during processing of the Authority checking for RACDCERT
Processing or the use of the associated programming interfaces as described above. It also
occurs during SSL/TLS processing, Communications Server Network Security Server
processing, or other processing using the R_datalib programming interfaces to read or
update RACF key ring information.
The authority to perform the individual management operations is determined by checking
the user's access to specific RACF profiles. This access check processing generally follows
the normal MVS DAC algorithm for general resources described above in the section on
discretionary access control, using specific resource names in the FACILITY class that
depend on the function requested. It also allows users with SPECIAL to perform certain of the
functions, as explained below.
Authority checking for RACDCERT Processing
Note: Since the check for sufficient authority to perform one of the management functions of
RACDCERT is performed by checking the user's authority to specific profiles using the
standard RACF access check algorithm, the claims in this section start with "AC" instead of
"SM".
In general to use RACDCERT users need either the SPECIAL attribute (AC.4-R9-RACF-1) or
 READ access to FACILITY resource IRR.DIGTCERT.function to issue RACDCERT
commands for themselves {SM.7::AC.4-R9-RACF-2};
 UPDATE access to FACILITY resource IRR.DIGTCERT.function to issue RACDCERT
commands for other users {SM.7::AC.4-R9-RACF-3};
 CONTROL access to FACILITY resource IRR.DIGTCERT.function to issue RACDCERT
commands for SITE and CERTAUTH certificates {SM.7::AC.4-R9-RACF-4}.
Authority The following tables describe the basic functions and the authorities used for each
RACDCERT function in more detail {SM.7::AC.4-R9-RACF-29}:
FUNCTION READ UPDATE CONTROL
ADD Add a certificate to
one's own ID
Add a certificate to
another user’s ID
Add a site or
certificate authority
certificate
ADDRING Create a key ring
for one’s own ID
Create a key ring for
another user’s ID
n/a
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FUNCTION READ UPDATE CONTROL
ADDTOKEN
(controlled only via
CRYPTOZ class)
n/a n/a n/a
ALTER Change the trust
status or label of
one’s own
certificate
Change the trust
status or label of
another user’s
certificate
Change the trust
status or label of a
site or certificate
authority certificate
ALTMAP Alter a mapping
associated with
one’s own ID
Alter a mapping
associated with
another user’s ID or
with MULTIID
n/a
BIND (Also see
CRYPTOZ class)
See BIND table See BIND table See BIND table
CHECKCERT (Note:
uses LIST as the
function in the DAC
check)
Check one’s own
certificate
Check another user’s
certificate
Check a site or
certificate authority
certificate
CONNECT See Connect tables See Connect tables See Connect tables
DELETE Delete one’s own
certificate
Delete another user’s
certificate
Delete a site or
certificate authority
certificate
DELMAP Delete a mapping
associated with
one’s own ID
Delete a mapping
associated with
another user’s ID or
with MULTIID
n/a
DELRING Delete one’s own
key ring
Delete another user’s
key ring
n/a
DELTOKEN
(controlled only via
CRYPTOZ class)
n/a n/a n/a
EXPORT See Export table See Export table See Export table
GENCERT See Gencert table See Gencert table See Gencert table
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FUNCTION READ UPDATE CONTROL
GENREQ Generate a request
based on one’s
own certificate
Generate a request
based on another
user’s certificate
Generate a request
based on a site or
certificate authority
certificate
IMPORT (also see
CRYPTOZ class)
See ADD above. See ADD above. See ADD above.
LIST List one’s own
certificate
List another user’s
certificate
List a site or
certificate authority
certificate
LISTMAP List mapping
information
associated with
one’s own ID
List mapping
information
associated with
another user’s ID or
MULTIID
n/a
LISTTOKEN (also see
CRYPTOZ class)
See LIST above See LIST above See LIST above
MAP Create a mapping
associated with
one’s own ID
Create a mapping
associated with
another user’s ID or
MULTIID
n/a
REMOVE Remove a
certificate from
one’s own key ring
Remove a site or
certificate authority
certificate from one’s
own key ring
Remove a certificate
from another user’s
key ring
REKEY Rekey one’s own
certificate
Rekey another user’s
certificate
Rekey a site or
certificate authority
certificate
ROLLOVER Rollover one’s own
certificate
Rollover another
user’s certificate
Rollover a site or
certificate authority
certificate
UNBIND (controlled
only via CRYPTOZ
class)
n/a n/a n/a
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This table describes the authorities needed to perform the BIND function to bind a certificate
to a PKCS#11 token:
USAGE One’s own certificate Another user’s
certificate
A site or certificate
authority
certificate
PERSONAL READ authority to
IRR.DIGTCERT.BIND
UPDATE authority to
IRR.DIGTCERT.BIND
CONTROL authority to
IRR.DIGTCERT.BIND
SITE
CERTAUTH
CONTROL authority to
IRR.DIGTCERT.ADD and
READ authority to
IRR.DIGTCERT.BIND
CONTROL authority to
IRR.DIGTCERT.ADD and
UPDATE authority to
IRR.DIGTCERT.BIND
UPDATE authority to
IRR.DIGTCERT.BIND
This table describes the authorities needed to perform the CONNECT function to connect a
certificate to one’s own key ring:
USAGE One’s own certificate Another user’s
certificate
A site or certificate
authority certificate
PERSONAL READ authority to
IRR.DIGTCERT.CONNECT
UPDATE authority to
IRR.DIGTCERT.CONNECT
CONTROL authority to
IRR.DIGTCERT.CONNECT
SITE
CERTAUTH
CONTROL authority to
IRR.DIGTCERT.ADD and
READ authority to
IRR.DIGTCERT.CONNECT
CONTROL authority to
IRR.DIGTCERT.ADD and
UPDATE authority to
IRR.DIGTCERT.CONNECT
UPDATE authority to
IRR.DIGTCERT.CONNECT
This table describes the authorities needed to perform the CONNECT function to connect a
certificate to another user’s key ring:
USAGE One’s own certificate Another user’s
certificate
A site or certificate
authority certificate
PERSONAL CONTROL authority to
IRR.DIGTCERT.CONNECT
CONTROL authority to
IRR.DIGTCERT.CONNECT
CONTROL authority to
IRR.DIGTCERT.CONNECT
SITE
CERTAUTH
CONTROL authority to
IRR.DIGTCERT.ADD and
CONTROL authority to
IRR.DIGTCERT.CONNECT
CONTROL authority to
IRR.DIGTCERT.ADD and
CONTROL authority to
IRR.DIGTCERT.CONNECT
CONTROL authority to
IRR.DIGTCERT.CONNECT
These tables describe the authorities needed to perform the EXPORT function:
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Function READ UPDATE CONTROL
EXPORT
(in CERT format)
Export one’s own
certificate
Export another
user’s certificate
Export a site or certificate
authority certificate
EXPORT
(in PKCS#7 format)
Export one’s own
certificate but
not the parent CA
chain
Export another
user’s certificate
but not the parent
CA chain
Export site or certificate
authority certificates or
the entire parent CA chain
for oneself or another
user.
EXPORT
(in PKCS#12 format.
Note: uses
EXPORTKEY as the
function in the DAC
check)
Export one’s own
certificate and
the private key
Export another
user’s certificate
and the private
key
Export a site or certificate
authority certificate and
the private key
This table describes the authorities needed to perform the GENCERT function:
SIGNWITH
option
chosen
To generate one’s
own certificate
To generate another
user’s certificate
To generate a site or
certificate authority
certificate
SIGNWITH
one’s own
certificate
READ authority to
IRR.DIGTCERT.ADD and
READ authority to
IRR.DIGTCERT.GENCERT
UPDATE authority to
IRR.DIGTCERT.ADD and
READ authority to
IRR.DIGTCERT.GENCERT
CONTROL authority to
IRR.DIGTCERT.ADD and
READ authority to
IRR.DIGTCERT.GENCERT
SIGNWITH
a SITE or
CERTAUTH
certificate
READ authority to
IRR.DIGTCERT.ADD and
CONTROL authority to
IRR.DIGTCERT.GENCERT
UPDATE authority to
IRR.DIGTCERT.ADD and
CONTROL authority to
IRR.DIGTCERT.GENCERT
CONTROL authority to
IRR.DIGTCERT.ADD and
CONTROL authority to
IRR.DIGTCERT.GENCERT
SIGNWITH
not
specified
READ authority to
IRR.DIGTCERT.ADD and
READ authority to
IRR.DIGTCERT.GENCERT
UPDATE authority to
IRR.DIGTCERT.ADD and
UPDATE authority to
IRR.DIGTCERT.GENCERT
CONTROL authority to
IRR.DIGTCERT.ADD and
CONTROL authority to
IRR.DIGTCERT.GENCERT
Authority Checking for R_datalib Processing
The R_datalib callable services provides access to some fields of certificates and key rings,
including when appropriate the private keys when stored in RACF. R_datalib allows reading,
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creation, or modification of key rings As with RACDCERT functions, the SPECIAL attribute
authorizes some functions. In addition, profiles in the RDATALIB class or in the FACILITY class
can authorize various R_datalib functions.
When using the FACILITY class, RACF will use resource names of the form
IRR.DIGTCERT.function to authorize the processing, where the descriptions below will
describe the applicable function values.
When using the RDATALIB class, RACF will use resource names of the form
<ringOwner>.<ringName>.function, where the descriptions below will the describe the
applicable function values.
The ringOwner must be in upper case. The ringName will be folded into upper cases
during profile checking. Rings differ only in case will be using the same profile {SM.7::AC.4-
R9-RACF-26}.
In the case the owner ID and the ring name are of their maximum limits, and you want to
create a discrete profile, it can be done by truncating the ring name from the end so that the
whole profile name length is 246 characters {SM.7::AC.4-R9-RACF-27}.
If the input Ring_name is of the virtual keyring form, a single ‘*’, the ring name part in the
resource will be IRR_VIRTUAL_KEYRING so that different profiles can be set up to control
access on real and virtual keyrings {SM.7::AC.4-R9-RACF-28}.
If the caller of R_datalib provides an owner ID of *TOKEN*, then the request specifies use of
a PKCS#11 cryptographic token in the ICSF TKDS, and all security checking occurs in ICSF
using the CRYPTOZ class. R_datalib does not do any checking in the FACILITY or RDATALIB
classes for these cases {SM.7::AC.4-R9-RACF-30}. For more information on this case see
Authority Checking for PKCS11 Cryptographic Tokens in the ICSF TKDS.
For the DatagetFirst, DataGetNext, and GetUpdateCode functions:
Using RDATALIB Checking for a Real Keyring {SM.7::AC.4-R9-RACF-5}:
Access to <ringOwner>.<ringName>.LST
in the RDATALIB class,
e.g. SERVER1.FTPRING1.LST
Action able to perform
READ DataGetFirst, DataGetNext:
list Server1’s ring named FTPring1, and
returns one’s own private key if the usage
is PERSONAL
GetUpdateCode:
return the sequence number of Server1’s
ring named FTPring1
UPDATE DataGetFirst, DataGetNext:
list Server1’s ring named FTPring1, and
returns another's private key if the usage
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Access to <ringOwner>.<ringName>.LST
in the RDATALIB class,
e.g. SERVER1.FTPRING1.LST
Action able to perform
is PERSONAL
CONTROL (or caller is RACF SPECIAL) DataGetFirst, DataGetNext:
list Server1’s ring named FTPring1, and
returns SITE/CA’s private key if the usage
is PERSONAL
Using RDATALIB Checking for a Virtual Keyring {SM.7::AC.4-R9-RACF-6}:
Virtual
keyring
owner
Resource Name Access Action able to perform
Ordinary ID,
e.g. USER1
USER1.IRR_VIRTUAL_KEYRING.LST READ DataGetFirst,
DataGetNext:
list USER1’s virtual
keyring, and returns the
private keys if the caller
is USER1, i.e. the owner
of the virtual keyring
GetUpdateCode:
return the sequence
number
UPDATE DataGetFirst,
DataGetNext:
list USER1’s virtual
keyring, and returns the
private key
GetUpdateCode:
return the sequence
number
CERTAUTH CERTIFAUTH.IRR_VIRTUAL_KEYRING.LST Read DataGetFirst,
DataGetNext:
list CERTAUTH’s virtual
keyring
GetUpdateCode:
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Virtual
keyring
owner
Resource Name Access Action able to perform
return the sequence
number
SITE SITECERTIF.IRR_VIRTUAL_KEYRING.LST Read DataGetFirst,
DataGetNext:
list SITE’s virtual keyring
GetUpdateCode:
return the sequence
number
Using FACILITY Checking {SM.7::AC.4-R9-RACF-7}:
Access to
IRR.DIGTCERT.LISTRING in
the FACILITY class
Action able to perform
READ DataGetFirst, DataGetNext:
list one’s own real or virtual ring, and returns one’s
own private key if the usage is PERSONAL
list one’s own real or virtual ring, and returns SITE/CA’s
private key if the usage is PERSONAL, if caller is
SPECIAL or has CONTROL to IRR.DIGTCERT.GENCERT in
the FACILITY class
GetUpdateCode:
return the sequence number of one’s own real or
virtual ring
UPDATE DataGetFirst, DataGetNext:
list another's real or virtual ring, and returns SITE/CA’s
private key if the usage is PERSONAL if caller is
SPECIAL or has CONTROL to IRR.DIGTCERT.GENCERT in
the FACILITY class
GetUpdateCode:
return the sequence number of another's real or virtual
ring
For the CheckStatus function:
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The call requires READ authority to resource IRR.DIGTCERT.LIST in the FACILITY class
{SM.7::AC.4-R9-RACF-8}.
For the IncSerialNum function:
The call requires either the SPECIAL attribute {SM.7::AC.4-R9-RACF-9} or
 READ authority to resource IRR.DIGTCERT.GENCERT in the FACILITY class if the caller
owns the certificate {SM.7::AC.4-R9-RACF-10};
 CONTROL authority to resource IRR.DIGTCERT.GENCERT in the FACILITY class for a
site or certificate authority certificate {SM.7::AC.4-R9-RACF-11}.
For the NewRing function:
No checking will be performed if the caller has the RACF SPECIAL attribute {SM.7::AC.4-R9-
RACF-12}.
Using RDATALIB Profile Checking: {SM.7::AC.4-R9-RACF-13}:
Access to <ringOwner>.<ringName>.UPD
in the RDATALIB class,
e.g. SERVER1.FTPRING1.UPD
Action able to perform
READ  add a new ring for Server1
named FTPring1
 remove all certificates from the
the existing ring named FTPring1
owned by Server1
Using FACILITY Profile Checking: {SM.7::AC.4-R9-RACF-14}:
Access to
IRR.DIGTCERT.ADDRING in the
FACILITY class
Access to
IRR.DIGTCERT.REMOVE in the
FACILITY class
Action able to
perform
READ n/a create one’s own
new ring
UPDATE n/a create another's
new ring
n/a READ remove
certificates from
one’s ring
n/a UPDATE remove
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Access to
IRR.DIGTCERT.ADDRING in the
FACILITY class
Access to
IRR.DIGTCERT.REMOVE in the
FACILITY class
Action able to
perform
certificates from
another's ring
For the Del Ring Function:
No checking will be performed if the caller has the RACF SPECIAL attribute {SM.7::AC.4-R9-
RACF-15}.
Using RDATALIB Profile Checking {SM.7::AC.4-R9-RACF-16}:
Access to <ringOwner>.<ringName>.UPD in the
RDATALIB class,
e.g. SERVER1.FTPRING1.UPD
Action able to perform
READ delete a ring owned by Server1
named FTPring1
Using FACILITY Profile Checking {SM.7::AC.4-R9-RACF-17}:
Access to IRR.DIGTCERT.DELRING in the FACILITY class Action able to perform
READ delete one’s own ring
UPDATE delete another's ring
For the DataRemove Function:
No checking will be performed if the caller has the RACF SPECIAL attribute {SM.7::AC.4-R9-
RACF-18}.
Using RDATALIB Profile Checking {SM.7::AC.4-R9-RACF-19}:
Access to <ringOwner>.<ringName>.UPD in
the RDATALIB class,
E.g. SERVER1.FTPRING1.UPD
Action able to perform
READ remove one’s own cert from
Server1’s ring named FTPring1
UPDATE remove one’s own or another's cert
from Server1’s ring named FTPring1
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Access to <ringOwner>.<ringName>.UPD in
the RDATALIB class,
E.g. SERVER1.FTPRING1.UPD
Action able to perform
CONTROL remove any type cert from Server1’s
ring named FTPring1
Using FACILITY Profile Checking {SM.7::AC.4-R9-RACF-20}:
Access to IRR.DIGTCERT.REMOVE in the FACILITY
class
Action able to perform
READ remove one’s own cert from
one’s ring
UPDATE remove any type cert from one’s
ring
CONTROL remove any type cert from
another's ring
In addition, if the DataRemove operation specifies CDDL_ATT_DEL_CERT_TOO, then RACF
will also check, IRR.DIGTCERT.DELETE whether using RDATALIB or FACILITY profiles
{SM.7::AC.4-R9-RACF-21}:
Access to IRR.DIGTCERT.DELETE in the
FACILITY class
Action able to perform
READ delete one’s own cert from RACF if it is not
connected to other rings
UPDATE delete one’s or another's cert from RACF if it
is not connected to other rings
CONTROL delete any type cert from RACF if it is not
connected to other rings
For the DataPut Function:
No checking will be performed if the caller has the RACF SPECIAL attribute {SM.7::AC.4-R9-
RACF-22}.
Note: In the following tables,
• Any usage = PERSONAL, CERTAUTH or SITE
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• Any type cert = certificate is owned by any regular ID, or by the site or a certificate
authority.
Using RDATALIB Profile Checking {SM.7::AC.4-R9-RACF-23}:
With READ Access to <ringOwner>.<ringName>.UPD, e.g. SERVER1.FTPRING1.UPD
Input cert is
not in RACF
Input cert is already in RACF Input cert is in RACF and
already connected to the
ring
with no
private key
with private
key
with no
private key
with private
key
Input
cert
only
Input
cert
and
private
key
 add one’s
own cert
 connect to
Server1’s
ring named
FTPring1
one’s own
cert with
usage
PERSONAL
only
if cert owned by caller
 connect to Server1’s ring
named FTPring1 with usage
PERSONAL only, other
usages cause error
 change the NOTRUST status
to TRUST if trust flag turns
on
if cert is not owned by caller,
error
if cert owned by caller
 re-connect to Server1’s
ring named FTPring1 with
usage PERSONAL only,
other usages cause error,
with new specified default
value
 change the NOTRUST
status to TRUST if trust flag
turns on
if cert is not owned by caller,
error
if cert owned
by caller
 re-add cert
with
private key
 connect to
Server1’s
ring named
FTPring1
with usage
PERSONAL
only, other
usages
if cert owned
by caller
 connect to
Server1’s
ring named
FTPring1
with usage
PERSONAL
only, other
usages
cause error
 change the
NOTRUST
status to
if cert owned
by caller
 re-add cert
with
private
key
 re-connect
to
Server1’s
ring
named
FTPring1
with usage
PERSONAL
if cert owned
by caller
 re-connect
to
Server1’s
ring
named
FTPring1
with usage
PERSONAL
only, other
usages
cause
error, with
new
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Input cert is
not in RACF
Input cert is already in RACF Input cert is in RACF and
already connected to the
ring
with no
private key
with private
key
with no
private key
with private
key
cause error
 change the
NOTRUST
status to
TRUST if
trust flag
turns on
if cert is not
owned by
caller, error
TRUST if
trust flag
turns on
if cert is not
owned by
caller, error
only, other
usages
cause
error, with
new
specified
default
value
 change
the
NOTRUST
status to
TRUST if
trust flag
turns on
if cert is not
owned by
caller, error
specified
default
value
 change the
NOTRUST
status to
TRUST if
trust flag
turns on
if cert is not
owned by
caller, error
With UPDATE Access to <ringOwner>.<ringName>.UPD, e.g. SERVER1.FTPRING1.UPD
Input cert is
not in RACF
Input cert is already in RACF Input cert is in RACF and
already connected to the
ring
with no
private key
with private
key
with no
private key
with private
key
Input
cert
only
 add any
type cert
 connect to
Server1’s
ring named
FTPring1
 connect to Server1’s ring
named FTPring1 one’s own
cert with any usage or
 connect to Server1’s ring
named FTPring1 another's
or SITE/CA’s cert with usage
 re-connect to Server1’s
ring named FTPring1 one’s
own cert with any usage or
 re-connect to Server1’s
ring named FTPring1
another's or SITE/CA’s cert
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Input cert is
not in RACF
Input cert is already in RACF Input cert is in RACF and
already connected to the
ring
with no
private key
with private
key
with no
private key
with private
key
one’s own
cert with
any usage
or
 connect
another's
or
SITE/CA’s
cert with
usage SITE
or
CERTAUTH
only,
PERSONAL
usage
causes
error
SITE or CERTAUTH only,
PERSONAL usage causes
error
 change the NOTRUST status
to TRUST if trust flag turns
on
with usage SITE or
CERTAUTH only,
PERSONAL usage causes
error, with new specified
default value
 change the NOTRUST
status to TRUST if trust
flag turns on
Input
cert
and
private
key
 add any
type cert
 connect to
Server1’s
ring named
FTPring1
any type
cert with
any usage
 re-add any
type cert
with
private key
under
original ID
 connect to
Server1’s
ring named
FTPring1
any type
cert with
any usage
 change the
NOTRUST
status to
TRUST if
trust flag
turns on
 connect to
Server1’s
ring named
FTPring1
any type
cert with
any usage
 change the
NOTRUST
status to
TRUST if
trust flag
turns on
 re-add any
type cert
with
private
key under
original ID
 re-connect
to
Server1’s
ring
named
FTPring1
any type
cert with
any usage,
with new
specified
default
value
 re-connect
to
Server1’s
ring
named
FTPring1
any type
cert with
any usage,
with new
specified
default
value
 change the
NOTRUST
status to
TRUST if
trust flag
turns on
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Input cert is
not in RACF
Input cert is already in RACF Input cert is in RACF and
already connected to the
ring
with no
private key
with private
key
with no
private key
with private
key
 change
the
NOTRUST
status to
TRUST if
trust flag
turns on
With CONTROL Access to <ringOwner>.<ringName>.UPD, e.g. SERVER1.FTPRING1.UPD
Input cert is
not in RACF
Input cert is already in RACF Input cert is in RACF and
already connected to the
ring
with no
private key
with private
key
with no
private key
with private
key
Input
cert
only
Input
cert
and
private
key
 add any
type cert
 connect to
Server1’s
ring named
FTPring1
any type
cert with
any usage
 connect to Server1’s ring
named FTPring1 any type
cert with any usage
 change the NOTRUST status
to TRUST if trust flag turns
on
 re-connect to Server1’s
ring named FTPring1 any
type cert with any usage,
with new specified default
value
 change the NOTRUST
status to TRUST if trust flag
turns on
 re-add cert
with
private key
under
original ID
 connect to
Server1’s
ring named
 connect to
Server1’s
ring named
FTPring1
any type
cert with
any usage
 change the
 re-add cert
with
private
key under
original ID
 re-connect
to
Server1’s
 re-connect
to
Server1’s
ring
named
FTPring1
any type
cert with
any usage,
with new
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Input cert is
not in RACF
Input cert is already in RACF Input cert is in RACF and
already connected to the
ring
with no
private key
with private
key
with no
private key
with private
key
FTPring1
any type
cert with
any usage
 change the
NOTRUST
status to
TRUST if
trust flag
turns on
NOTRUST
status to
TRUST if
trust flag
turns on
ring
named
FTPring1
any type
cert with
any usage,
with new
specified
default
value
 change
the
NOTRUST
status to
TRUST if
trust flag
turns on
specified
default
value
 change the
NOTRUST
status to
TRUST if
trust flag
turns on
Using FACILITY Profile Checking {SM.7::AC.4-R9-RACF-24}:
Certificate does not exist in RACF Database
Access to
IRR.DIGTCERT.ADD in the
FACILITY class
Access to
IRR.DIGTCERT.CONNECT in the
FACILITY class
Action able to perform
READ READ  add one’s own cert
 connect one’s own cert with
usage PERSONAL to one’s
own ring
CONTROL READ  add one’s own cert
 connect one’s own cert with
any usage to one’s own ring
UPDATE UPDATE  add one’s own or another's
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cert
 connect one’s own or
another's cert with usage
PERSONAL to one’s ring or
 connect SITE/CA’s cert with
SITE/CERTAUTH usage to
one’s own ring
CONTROL UPDATE  add any type cert
 connect one’s own or
another's cert with usage
PERSONAL to one’s ring or
 connect any type cert with
usage SITE/CERTAUTH to
one’s ring
UPDATE CONTROL  add one’s own or another's
cert
 connect any type cert with
usage PERSONAL to any ring
or
 connect SITE/CA’s cert with
any usage to any ring
CONTROL CONTROL  add any type cert
 connect any type cert with any
usage to any ring
Certificate exists in RACF Database with no private key but private key is specified
Access to
IRR.DIGTCERT.ADD in the
FACILITY class
Access to
IRR.DIGTCERT.CONNECT in the
FACILITY class
Action able to perform
READ READ  re-add one’s own cert
with private key
 change the NOTRUST
status of the connected
cert to TRUST if trust flag
turns on
 connect one’s own cert
with usage PERSONAL
to one’s own ring
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CONTROL READ  re-add one’s own cert
with private key
 change the NOTRUST
status of the connected
cert to TRUST if trust flag
turns on
 connect one’s own cert
with any usage to one’s
own ring
UPDATE UPDATE  re-add one’s own or
another's cert with private
key
 change the NOTRUST
status of the connected
cert to TRUST if trust flag
turns on
 connect one’s own or
other’s cert with usage
PERSONAL to one’s ring
or
 connect SITE/CA’s cert
with SITE/CERTAUTH
usage to one’s own ring
CONTROL UPDATE  re-add any type cert with
private key
 change the NOTRUST
status of the connected
cert to
TRUST/HIGHTRUST if
trust flag turns on
 connect one’s own or
other’s cert with usage
PERSONAL to one’s ring
or
 connect any type cert with
usage SITE/CERTAUTH
to one’s ring
UPDATE CONTROL  re-add one’s own or
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other’s cert with private
key
 change the NOTRUST
status of the connected
cert to TRUST if trust flag
turns on
 connect any type cert with
usage PERSONAL to any
ring or
 connect SITE/CA’s cert
with any usage to any
ring
CONTROL CONTROL  re-add any type cert with
private key
 change the NOTRUST
status of the connected
cert to
TRUST/HIGHTRUST if
trust flag turns on
 connect any type cert
with any usage to any
ring
Certificate already exists in RACF Database and no private key is input
Access to
IRR.DIGTCERT.ADD
in the FACILITY
class
Access to
IRR.DIGTCERT.CONNECT
in the FACILITY class
Access to
IRR.DIGTCERT.ALTER
in the FACILITY class
(will be checked if
changing status from
NOTRUST to
TRUST/HIGHTRUST is
requested)
Action able to
perform
n/a READ READ  connect one’s
own cert with
usage
PERSONAL to
one’s own ring
 change the
NOTRUST status
of the connected
cert to TRUST if
trust flag turns on
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CONTROL READ READ  connect one’s
own cert with any
usage to one’s
own ring
 change the
NOTRUST status
of the connected
cert to TRUST if
trust flag turns on
n/a UPATE READ – one’s own cert
UPDATE – other’s cert
CONTROL – SITE/CA’s
cert
 connect one’s
own or other’s
cert with usage
PERSONAL to
one’s ring or
 connect
SITE/CA’s cert
with
SITE/CERTAUTH
usage to one’s
own ring
 change the
NOTRUST status
of the connected
cert to
TRUST/HIGHTR
UST if trust flag
turns on
CONTROL UPDATE READ – one’s own cert
UPDATE – other’s cert
CONTROL – SITE/CA’s
cert
 connect one’s
own or other’s
cert with usage
PERSONAL to
one’s own ring or
 connect
SITE/CA’s cert
with
SITE/CERTAUTH
usage to one’s
own ring
 change the
NOTRUST status
of the connected
cert to
TRUST/HIGHTR
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UST if trust flag
turns on
n/a CONTROL READ – one’s own cert
UPDATE – other’s cert
CONTROL – SITE/CA’s
cert
 connect any type
cert with usage
PERSONAL to
any ring or
 connect
SITE/CA’s cert
with any usage to
any ring
 change the
NOTRUST status
of the connected
cert to
TRUST/HIGHTR
UST if trust flag
turns on
CONTROL CONTROL READ – one’s own cert
UPDATE – other’s cert
CONTROL – SITE/CA’s
cert
 connect any type
cert with any
usage to any ring
 change the
NOTRUST status
of the connected
cert to
TRUST/HIGHTR
UST if trust flag
turns on
For the DataRefresh Function:
No checking will be performed if the caller has the RACF SPECIAL attribute, otherwise if the
DIGTCERT class is SETR RACLISTed then the caller needs class authority (CLAUTH) to the
DIGTCERT class {SM.7::AC.4-R9-RACF-25}.
Authority Checking for PKCS11 Cryptographic Tokens in the ICSF TKDS
DAC for PKCS#11 Cryptographic Tokens in the ICSF TKDS occurs using profiles in the
CRYPTOZ resource class, using the basic MVS DAC algorithm described above.
The access control defined in the PKCS#11 standard was designed for systems that have no
security manager. Access to token information in the standard is granted based on the
knowledge of a PIN. In the definition there are two types of users, the standard user (User)
and the security officer (SO). Each has their own PIN. The SO can initialize a token (zero the
contents) and set the User’s PIN. The SO can also access the public objects on the token but
not the private ones. The User has access to the private objects on a token and has the
power to change his or her own PIN. The User cannot reinitialize the token. The role one is
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allowed to take depends on the PIN entered. Thus a single person can fill both roles by
having knowledge of both PINs.
On z/OS these two roles will be simulated by using SAF profiles in a new Class called
CRYPTOZ. There will be no PINs. Each token defined will have a unique token name (label)
up to 32 characters in length. The permitted characters are alphanumeric, national (@,#,$)
or period (.). The first character must be alphabetic or national. Lowercase letters are
permitted but will be folded to uppercase. (This is the same naming restriction as PKDS
labels.) There will be two CRYPTOZ Class resources checks performed for tokens:
 USER.token-name -- Controls the User role
 SO.token-name -- Controls the SO role
The different access levels provide the following functionality:
 The 3 standard PKCS#11 access types (User R/W, SO R/W, User R/O)
o R/O vs R/W not end-user controlled
 Plus 3 z/OS unique access types
o Weak SO -- An SO that can modify CAs contained in a token but not initialize
the token
o Strong SO -- An SO that can add or remove private objects in a token (e.g., a
server administrator)
o Weak User -- A user that cannot change the trusted CAs contained in a token
CRYPTOZ DAC Table {SM.7::AC.4-R9-ICSF-1}:
CRYPTOZ
Resource
Name
Access of:
READ
Access of: UPDATE Access of: CONTROL
SO.token-label Weak SO -- read
/ create / delete
/ modify / use
public objects
SO R/W -- Weak SO plus
create / delete token
Strong SO -- SO RW plus
read (but not use)
private objects, create /
delete / modify private
objects
USER.token-
label
User R/O -- read
/ use public and
private objects.
Weak User -- User R/O plus
create / delete / modify
private and public objects
(cannot add / delete / modify
certificate authority objects)
User R/W -- Weak User
plus add / delete /
modify certificate
authority objects
Group Profiles
The base segment of a group profile within RACF contains (among other data not relevant
for the security functions defined in this Security Target) the following:
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Name Description
GROUPNAME Name of the group
OWNER Owner of the group profile
SUPGROUP The profile’s superior group
MODEL Name of a profile to be used as a model
TERMUACC or NOTERMUACC The group’s terminal authorization
The OMVS segment of the group profile contains the group’s z/OS UNIX group identifier in
the GID field.
Administrators have several choices when establishing OMVS information for groups:
• They may define the OMVS segment for groups completely manually, via ADDGROUP
or ALTGROUP with the OMVS keyword, and explicit specification of the value of the
GID {SM.1::SM.1-R11-RACF-5}.
• They may define the OMVS segment via ADDGROUP or ALTGROUP with the OMVS
keyword but allowing RACF to automatically choose the GID via the AUTOGID
keyword , in conjunction with the BPX.NEXT.USER profile in the FACILITY class, where
the administrator specifies an APPLDATA field containing the allowable range of
automatically-assigned GIDs. RACF will then assign the lowest available unique GID
and update the APPLDATA information to indicate the GID it used {SM.1::SM.1-R11-
RACF-6}.
• They may define the OMVS information implicitly, through use of the
BPX.DEFAULT.USER profile in the FACILITY class. With the profile, the APPLDATA
specifies the RACF group name of a group that has an OMVS segment, when the
system needs to determine the GID of a user's default group, and the group does not
have an OMVS segment, the system will temporarily use the GID information from
the group named in BPX.DEFAULT.USER {SM.1::SM.1-R11-RACF-7}.
• They may define the OMVS information automatically, by specifying the
BPX.NEXT.USER profile in the FACILITY class to record the allowable range of
automatically-assigned GIDs (as above), and the BPX.UNIQUE.USER profile to indicate
that whenever a user whose default (or current connect) group has no OMVS
segment makes use of UNIX functions, RACF should automatically create a
permanent OMVS segment for that group. {SM.1::SM.1-R11-RACF-8}. This process
will also occur if someone inquires about the GID for a group that does not have one
using the getgmap() callable service {SM.1::SM.1-R11-RACF-9}.
LDAP LDBM Groups
LDBM supports group definitions. These group definitions allow for a collection of names to
be easily associated for access control checking. LDBM supports static (where the members
are defined individually {SM.2::SM.2-R8-LDAP-1}), dynamic (where membership is
determined using one or more LDAP search expressions {SM.2::SM.2-R8-LDAP-2}), and
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nested (a group that references other group entries that can be static, dynamic or nested
groups {SM.2::SM.2-R8-LDAP-3}) group entries.
LDAP also supports, via the CDBM, an LDAP administrative group whose members have
specific LDAP administrative capabilities based on the LDAP administrative roles assigned to
them. When authenticating an LDAP user who is a member of the LDAP administrative
group, LDAP does not make use of (gather) additional group information for that user
{SM.2::SM.2-R13-LDAP-5}.
When configured to search SDBM for a user's groups, LDAP will convert those groups into
SDBM DNs and add them to the LDBM user's set of groups, making them available for use in
LDBM ACLs for authorization checking {SM.2::SM.2-R10-LDAP-4}.
User roles and attributes
User roles and attributes are extraordinary capabilities, restrictions, or environments that
can be assigned to a user, either all of the time or when the user is connected to a specific
group or groups. User attributes are stored and managed within the RACF database.
When a role or attribute is to apply only to a specific group or groups, it is specified at the
group level and is called a group-related user attribute. For example, user attributes that are
specified in an ADDUSER or ALTUSER command are stored in the user’s profile and are in
effect regardless of the group to which the user is connected {SM.1::SM.1.14}.
RACF maintains the roles and attributes specified in this section in fields in the user profile.
The distinction between roles and attributes in this Security Target is artificial and reflects
the definition in Chapter 5 for roles and user attributed. RACF does not make this distinction
and the IBM guidance describes all of the following as user attributes.
Apart from the explicitly mentioned roles and attributes described below, users are assigned
certain roles implicitly:
 Users implicitly are in the “user” role which allows them to change their own
authentication data
 Users can be assigned the operator role by authorizing them to issue an operator
command in the command’s own profile.
 Ownership of objects entitles users to change the object’s security attributes.
Ownership for non-UNIX objects is identical to ownership of the profile protecting the
object.
For LDAP LDBM users, the LDAP server maintains the roles and attributes specified below (in
LDAP Roles and LDAP Attributes) in the LDAP LDBM or CDBM back-end, or specified via RACF
resource profiles.
RACF Roles
SPECIAL and group-SPECIAL
A user who has the SPECIAL attribute at the system level can issue all RACF commands (but
not all operands. There are AUDITOR-only operands related to the configuration of the audit
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function that only a user with the AUDITOR attribute is allowed to use) {SM.1::SM.1.15}. The
SPECIAL attribute gives the user full control over all of the RACF profiles in the RACF
database. The SPECIAL attribute can also be assigned at the group level. Such a user with
the group-SPECIAL attribute has full control over all of the profiles within the scope of the
group.
A user with the SPECIAL role in his user profile is regarded as a system administrator. He
can:
 add, delete, list and modify user, group, DATASET and other profiles {SM.1::SM.1.16}
 list and define RACF general options (except options related to auditing)
{SM.1::SM.1.17}
A system administrator can delegate administrative activities to users such that they can
administer profiles belonging to a defined group. He does this by assigning such users the
group-SPECIAL attribute. Those users then have administrative capabilities within the group
they were assigned the group SPECIAL attribute {SM.1::SM.1.18}. Users with the attribute
group-SPECIAL can not use general RACF options of the SETROPTS command (except for the
REFRESH GENERIC and LIST operands) {SM.1::SM.1.19}.
AUDITOR and group-AUDITOR
The AUDITOR attribute is given only to users who are responsible for auditing RACF security
controls and functions. To provide a check and balance on RACF security measures, the
AUDITOR attribute should be given to security or group administrators other than those who
have the SPECIAL attribute. The AUDITOR attribute can also be assigned at the group level.
Such a user with the group-AUDITOR attribute can control the audit configuration within the
scope of the group where the attribute was assigned {SM.1::SM.1.20}.
A user with the AUDITOR attribute can define and modify the audit related options in user
and the auditor related options for resource profiles {SM.1::SM.1.21}. This allows him to
define which activities are to be recorded in the audit trail. He can also list the content of
any profile and set the system wide audit related options using the SETROPTS command.
Those options are:
 AUDIT or NOAUDIT (for each profile class) {SM.1::SM.1.22}
 CMDVIOL or NOCMDVIOL {SM.1::SM.1.23}
 LOGOPTIONS (for each profile class) {SM.1::SM.1.24}
 OPERAUDIT or NOOPERAUDIT {SM.1::SM.1.25}
 SAUDIT or NOSAUDIT {SM.1::SM.1.26}
 SECLABELAUDIT or NOSECLABELAUDIT {SM.1::SM.1.27}
Audit configuration can also be delegated at the group level by giving the group-AUDITOR
attribute to a user.
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A user with the group-Auditor attribute can define and modify the audit related options in
user, and resource profiles associated with his group {SM.1::SM.1.28}. He can not modify or
set audit related attributes that operate system-wide {SM.1::SM.1.29}. Note that a user with
SPECIAL controls the activation/deactivation of the OMVS audit related classes (DIRACC,
DIRSRCH, FSOBJ, FSSEC, IPOBJ, PROCACT and PROCESS)
OPERATIONS and group-OPERATIONS
A user who has the OPERATIONS attribute has full access authorization to all RACF-protected
resources in the DATASET, DASDVOL, GDASDVOL and TAPEVOL classes except when
restricted by an access list entry granting less authority {SM.1::SM.1.30}. The OPERATIONS
attribute can also be assigned at the group level {SM.1::SM.1.31}.
Operator
A user who is allowed to issue operator commands has the role of an operator. To be able to
issue operator commands a user must have been authorized to the profiles in the
OPERCMDS class protecting the operator commands. Permission to issue operator
commands can be given on a per command basis. For the purpose of this Security Target a
user who has been authorized to at least one profile in the OPERCMDS class protecting MVS
and JES2 operator commands is defined to have the role of an operator.
z/OS UNIX superuser
A user operating with an effective UID of zero or a user that has been authorized to the
BPX.SUPERUSER profile in the FACILITY class is defined to have the role of a z/OS UNIX
superuser.
Pseudo user
A user defined with the NOPASSWORD, NOPHRASE, and NOOIDCARD parameter in his user
profile is defined as having the role of a "pseudo-user". The TOE prohibits that a user with
those attributes can log into the TOE. Those IDs can be used by SURROGAT-submitted batch
jobs or by started procedures defined in the STARTED class or the started procedures table.
RACF Attributes
CLAUTH
If a user has the CLAUTH attribute in a class, RACF allows the user to define profiles in that
class {SM.1::SM.1.32}.
Users receive the CLAUTH attribute on a class-by-class basis. The CLAUTH attribute can be
assigned at the user or group level {SM.1::SM.1.33}.
A user with the CLAUTH(USER) attribute can add and modify users except for setting or
modifying the following attributes:
 SPECIAL or NOSPECIAL {SM.1::SM.1.34}
 AUDITOR or NOAUDITOR {SM.1::SM.1.35}
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 OPERATIONS or NOOPERATIONS {SM.1::SM.1.36}
REVOKE
A user can be prevented from entering the system by assigning the REVOKE attribute
{SM.1::SM.1.37}. This attribute is useful when a user needs to be prevented from entering
the system, but cannot be deleted using the DELUSER command because the user still owns
RACF resource profiles. It is also useful when a user must be temporarily prevented from
using the system for some reason.
User accounts can be revoked automatically after a period of inactivity {SM.1::SM.1.38}.
This applies also to accounts that have never been active {SM.1::SM.1.39}.
LDAP Roles
The TOE supports the LDAP roles:
1. administrator {SM.1::SM.1-R8-LDAP-1},
2. member of the administrative group {SM.1::SM.1-R13-LDAP-13}
3. for basic replication :masterServer {SM.1::SM.1-R8-LDAP-2} (used as the master in
LDAP replication processing), and peerServer {SM.1::SM.1-R8-LDAP-3} (used as a
peer in LDAP replication processing),
4. for advanced replication: supplier (a server thast sends changes to another
(consumer) server , consumer (a server that receives changes via replication from
another (supplier) server; {SM.1::SM.1-R12-LDAP-9}
5. and (by default) “end user”.{SM.1::SM.1-R12-LDAP-10}
Three non-default roles (administrator, and for basic replication, masterServer and
peerServer) are defined within the LDAP configuration file.
End users have no pre-defined administrative rights, though under the control of access lists
in the LDAP directory they may be allowed to create,or delete objects, or even manipulate
the access lists for objects.
For advanced replication, a replication context is created as an entry in the directory with
the auxiliary objectclass ibm-replicationContext that identifies the root of a replicated
subtree. It can be added to any entry. The replication configuration information is
maintained in a set of entries created below the base of a replication context. If there is
more than one replication context present in the same subtree, the replication configuration
information under the child replication context entry is used while the replication
configuration under the parent entry is ignored. If the ibm-replicationContext auxiliary
objectclass is added to a non-suffix level entry in the directory, explicit aclEntry and
entryOwner attribue values are required. For advanced replication, supplier credentials are
created in the directory associated with the replica subtree that identify the servers that are
supplied (replicated to) by each server, and on a consumer server a credentials entry is
required for each supplier and verified using a simple or SASL EXTERNAL bind. {SM.1::SM.1-
R12-LDAP-11}
When configuring LDAP LDBM basic replication, replicas may be read-write, or read-only
{SM.1::SM.1-R8-LDAP-5}. A peerServer can replicate its changes to other read-write
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replicas, and has the ability to update all data, bypassing all access list (ACL) controls
{SM.1::SM.1-R8-LDAP-6}. A masterServer can replicate its changes to other read-write or
read-only replicas {SM.1::SM.1-R8-LDAP-7}. A particular server may be both a peerServer to
other read-write replicas, and a masterServer to read-only replicas {SM.1::SM.1-R8-LDAP-8}.
For advanced replication, a read-only replica is a consumer replica. If the replica can both
read and write, the replica is both a consumer and supplier replica. {SM.1::SM.1-R12-LDAP-
12}
The LDAP root Administrator has the ability to define LDAP groups to assist in the
management of access rights and privileges {SM.1::SM.1-R13-LDAP-4}. Those administrator
defined groups are not considered to be roles in the sense of the CC requirement
FMT_SMR.1 but are just ways to manage access rights more easily.
The LDAP root Administrator also has complete access rights to all data in the LDAP LDBM
and CDBM databases {SM.1::SM.1-R13-LDAP-14}.
{SM.1::SM.1-R13-LDAP-15} Additionally, the LDAP root Administrator can define members of
the LDAP administrative group via entries in the CDBM database. The LDAP root
Administrator may define those members (via DN) within the directory subtree under
cn=admingroup,cn=configuration or within the directory subtree under
cn=safadmingroup,cn=configuration. With either method, the LDAP root Administrator may
assign LDAP administrative roles to the administrative group members. The difference
between the methods is that for members defined under
cn=safadmingroup,cn=configuration the roles are derived by querying the user's access to
RACF resources in the LDAP class, while for members defined under
cn=admingroup,cn=configuration the user's administrative roles are specified directly within
the CDBM entry for the user.
Briefly, The administrative roles supported in the z/OS LDAP server are:
 Directory data administrator – Intended to administer all DIT data (LDBM and
cn=ibmpolicies in CDBM)
 No administrator – Intended to quickly revoke an administrative group member's
administrative privileges.
 Operational administrator – Intended to request persistent search via control
 Password administrator – Intended to administer user passwords, for example
Help Desk resetting a password of users in the LDBM backend.
 Replication administrator – Intended to administer advanced replication
configurations.
 Root administrator – Super user (sum of all administrative roles, excluding NoAdmin)
 Schema administrator – Intended to administer the schema.
 Server configuration group member – Intended to administer cn=configuration.
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In more detail, these are the characteristics of each of the LDAP administrative roles:
 {SM.1::SM.1-R13-LDAP-16} Directory Data Administrator – Users assigned
this role have unrestricted access to the entries in the LDBM backend and the
cn=ibmpolicies tree in the CDBM backend. aclEntry values are ignored if the bound
user has this administrative role. Filtered ACLs will still be applied, but cannot
augment any permissions explicitly denied by this role definition. The Directory
Data Administrator has the following authority in the directory:
 add, modify and delete access to Master Server DN and replication supplier
entries of a consumer replica when also assigned the Schema
Administrator and Server Configuration Group Member administrative
roles. Note that any configurations in ds.conf are not included.
 complete access to the cn=replication, cn=configuration entry in the
CDBM backend
 modify access to the ibm-slapdAdminPW attribute in their own configuration
entry
 complete access to entries in the LDBM backend. However, for setting the
password of any entry, the Directory Data Administrator must abide by the
normal password policy rules (if there are any). Users in this role cannot
change the password of other administrative group members that exist in the
directory .
 read, search, and compare access to all entries in and under the
cn=configuration suffix in the CDBM backend
 ibm-slapdAdminDN, ibm-slapdAdminPW, and ibm-
slapdAdminGroupEnabled attributes under the cn=configuration
entry
 ibm-slapdAdminPW attribute under other local administrative group
member entries, and
 passwords of advanced replication supplier credential entries (Master
Server DNs) .
 read access to the cn=schema entry
 cannot add or delete entries under cn=replication, cn=configuration
 {SM.1::SM.1-R13-LDAP-17} No administrator – Users assigned this role have
no administrative privileges. By defining this role the LDAP root administrator
revokes all the administrative privileges of an administrative group member. The No
Administrator has the following authority in the directory:
 modify access to the ibm-slapdAdminPW attribute in their own configuration
entry
 read, search, and compare access to all entries in and under the
cn=configuration suffix in the CDBM backend except for
 ibm-slapdAdminDN, ibm-slapdAdminPW and ibm-
slapdAdminGroupEnabled attributes under the cn=configuration
entry
 ibm-slapdAdminPW attribute under other local administrative group
member entries, and
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 passwords of advanced replication supplier credential entries (Master
Server Dns).
 read access to cn=schema entries
 access to the LDBM backend through normal ACL evaluation. Filtered ACLs will
still be applied, but cannot augment any permissions explicitly DENIED by this
role definition. See <ref to ACL chapter> for more information.
 {SM.1::SM.1-R13-LDAP-18 Operational Administrator - Users assigned this role
can perform persistent searches. aclEntry values are ignored when processing this
role. ACL Filters do not apply. The operational administrator has the following
authority in the directory:
 can include the PersistentSearch control on searches.
 has modify access to ibm-slapdAdminPW attribute in their own
configuration entry
 has read access to all entries in and under the cn=configuration suffix in the
CDBM backend except for
 ibm-slapdAdminDN, ibm-slapdAdminPW, and ibm-
slapdAdminGroupEnabled attributes under the cn=configuration
entry
 ibm-slapdAdminPW attribute under other local administrative group
member entries, and
 passwords of advanced replication supplier credential entries (Master
Server DNs)
 has read access to the cn=schema entry
 has read access to the , LDBM backend and cn=ibmpolicies in CDBM
 {SM.1::SM.1-R13-LDAP-19} Password administrator – Users assigned this role
can unlock other user’s accounts or change passwords of users in the LDBM backend.
Password policy constraints set by the server do not apply to users assigned the
password administrator role. This role has access to the LDBM backend through
normal ACL evaluation. Filtered ACLs will still be applied, but cannot augment any
permissions explicitly DENIED by this role definition. See <ref to ACL chapter> for
more information. The password administrator has the following authority in the
directory:
 has modify access to the ibm-slapdAdminPW attribute in their own
configuration entry
 has read, search, and compare access to all the entries in and under
cn=configuration except
 ibm-slapdAdminDN, ibm-slapdAdminPW and ibm-
slapdAdminGroupEnabled attributes under the cn=configuration
entry
 ibm-slapdAdminPW attribute under other local administrative group
member entries, and
 passwords of advanced replication supplier credential entries (Master
Server DNs)
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 has read, search, and compare access to the cn=schema entry
 can unlock the user accounts or set the password without following normal
password policy rules for all the users in backends except global
administrative group members. This means users with the password
administrator role:
 have read, write and search access to the userpassword attribute and
read, write, search and compare access to the pwdChangedTime
attribute.
 can add, delete, and modify the ibm-pwdAccountLocked attribute
only if the new value of the attribute is false.
 can delete pwdFailureTime, pwdAccountLockedTime,
pwdExpirationWarned,and pwdGraceUseTime attribute values for
all users.
 {SM.1::SM.1-R13-LDAP-20} Replication administrator – Users assigned the
Replication Administrator role can update advanced replication topology objects.
This role has access to the LDBM backend through normal ACL evaluation. Filtered
ACLs will still be applied, but cannot augment any permissions explicitly DENIED by
this role definition. See <ref to ACL chapter> for more information. The Replication
administrator has the following authority in the directory
 has no access to Master DN and replication supplier entries in a consumer
replica
 has read, write, search, and compare access to cn=replication,
cn=configuration entry in the CDBM backend
 has modify access to the ibm-slapdAdminPW attribute in their own
configuration entry
 has read access to all the entries in and under cn=configuration except
 ibm-slapdAdminDN, ibm-slapdAdminPW and ibm-
slapdAdminGroupEnabled attributes under the cn=configuration b
entry
 ibm-slapdAdminPW attribute under other local administrative group
member entries, and
 passwords of advanced replication supplier credential entries (Master
Server DNs).
 can issue the following extended operations: Cascading control
replication, Control replication queue, Control replication, Control
replication error log, Quiesce or Unquiesce replication context, and
Replication topology. .
 has read access to the cn=schema entry
 has read, write, search ,compare, add and delete access to all the replication
topology objects in the backends. The determination of replication objects is
based on the presence of following objectclasses in the entry - ibm-
replicationcontext, ibm-replicagroup, ibm-replicasubentry, ibm-
replicationAgreement, ibm-replicationCredentials, ibm-
replicationCredentialsSimple, ibm-replicationCredentialsExternal, ibm-
replicationWeeklySchedule, ibm-replicationDailySchedule, and ibm-
replicationfilter.
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 {SM.1::SM.1-R13-LDAP-21} Root administrator – Users assigned this role has
the same access to data in the the LDAP server as the LDAP root administrator
(adminDN in ds.conf). This role has permissions of all other roles except No
administrator.
 {SM.1::SM.1-R13-LDAP-22} Schema administrator – Users assigned this role
have unrestricted access to the schema back-end only. This role has access to the
LDBM backend through normal ACL evaluation. Filtered ACLs will still be applied, but
cannot augment any permissions explicitly DENIED by this role definition. See <ref to
ACL chapter> for more information. The Schema administrator has the following
authority in the directory:
 modify access to the cn=schema entry
 add, modify, and delete access to the Master Server DN and replication
supplier entries (cn=configuration in the CDBM backend) of a consumer
replica when the user also has the directory data administrator and
server configuration group member roles.
 modify access to the ibm-slapdAdminPW attribute in their own configuration
entry
 read access to all the entries in and under cn=configuration except
 ibm-slapdAdminDN, ibm-slapdAdminPW and ibm-
slapdAdminGroupEnabled attributes under the cn=configuration
entry
 ibm-slapdAdminPW attribute under other local administrative group
member entries, and
 passwords of advanced replication supplier credential entries (Master
Server DNs).
 read, write, search and compare access to the cn=schema entry
 {SM.1::SM.1-R13-LDAP-23} Server configuration group member – Users
assigned this role have restricted update access to the cn=configuration entries in
the CDBM backend. This role has access to the LDBM backend through normal ACL
evaluation. Filtered ACLs will still be applied, but cannot augment any permissions
explicitly DENIED by this role definition. See <ref to ACL chapter> for more
information. The Server configuration group member has following authority in
the directory:
 add, modify and delete access to all the entries in the CDBM
cn=configuration backend except the following
 ibm-slapdAdminDN, , and ibm-slapdAdminGroupEnabled
attributes under the cn=configuration entry
 entries under the cn=AdminGroup, cn=configuration entry
 add, modify, and delete access to the Master Server DN and replication
supplier entries in the cn=configuration entry in the CDBM backend of a
consumer replica when the user is also assigned directory data
administrator and schema administrator roles.
 modify access to the ibm-slapdAdminPW attribute in its own configuration
entry
 read access to all the entries in and under cn=configuration except
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 ibm-slapdAdminDN, ibm-slapdAdminPW and ibm-
slapdAdminGroupEnabled attributes under the cn=configuration
entry
 ibm-slapdAdminPW attribute under other local administrative group
member entries, and
 passwords of advanced replication supplier credential entries (Master
Server DNs).
 read access to the cn=schema entry
{SM.1::SM.1-R13-LDAP-24} When the administrator assigns LDAP administrative roles via
cn=safadmingroup, cn=configuration the DN specified must eventually lead to a RACF user
ID that has READ authorization to one or more of the RACF resources specified below. DNs
satisfying that requirement might be for SDBM entries, a DNs from as SSL client certificate, a
DN of an LDBM entry participating in native authentication, or a Kerberos mapped DN. The
resource names used have the form domain-name.ADMINROLE.role where:
 domain-name is the value specified in the ibm-slapdSAFSecurityDomain attribute
of the cn=configuration entry. The LDAP server uses the value in this attribute as
the first part of the RACF defined administration role when it does SAF authorization
checking on security related profiles for the administration roles.
 role is one of the following values:
 CONFIG (for Server configuration group member)
 DIRDATA (for Directory Data Administrator)
 NOADMIN (for No Administrator)
 OPER (for Operational Administrator)
 PASSWD (for Password Administrator)
 REPL (for Replication Administrator)
 ROOT (for Root Administrator)
 SCHEMA (for Schema Administrator)
LDAP Attributes
The ibm-nativeId LDAP attribute specifies the RACF user ID associated with an LDAP user
authenticating to LDAP to access LDAP LDBM data.
Several attributes and object classes determine group membership for LDAP groups:
• For static groups in the accessGroup, groupOfNames, ibm-staticGroup object classes,
the values of the member attribute determine group membership.
• For static groups in the groupOfUniquenames object class the values of the
uniqueMember attribute determine group membership.
• For dynamic groups the scope and search filters contained in the values of the
memberURL attribute determine group membership.
• For nested groups the values of the ibm-memberGroup attribute determine the
groups that are members of the nested group.
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User Revocation
User revocation can take two forms in the TOE:
• Revocation of the RACF user ID associated with a user: As all user authentication
occurs via RACF, and all users have a RACF identity, the administrator can revoke a
user by using the ALTUSER command with the REVOKE operand {SM.1::SM.1-R8-REV-
1}. Note that this will not cover immediate revocation, but it will prevent the user
from entering the system in the future.
• Revocation of a user’s digital certificate: For certificates registered in RACF via the
RACDCERT command, the administrator can delete the certificate using RACDCERT
{SM.1::SM.1-R8-REV-2}. This will prevent the system from recognizing that certificate
in the future and associating it with the user’s RACF identity. For certificates supplied
by PKI Services, the administrator can publish the certificate on the Certification
Revocation List (CRL) which will signal to applications that support CRLs or the Online
Certificate Status Protocol that the certificate is no longer valid and may not be used
for authentication {SM.1::SM.1-R8-REV.3}.
For immediate revocation of a user in extreme situations a simple ALTUSER or certificate
revocation may not suffice. In that case the administrator may determine which applications
the user has access to (e.g., TSO/E, z/OS UNIX System Services, FTP server, HTTP server,
LDAP). The administrator can then issue appropriate system or application commands to
determine if the user is active in the system, and if so issue the appropriate system or
application commands to terminate the user’s sessions.
For example, for a TSO/E user the administrator could issue the CANCEL U=user-ID
command. For a batch job the administer could issue CANCEL jobname.
As a final resort the administrator could stop servers such as the HTTP server, FTP server, or
LDAP server if the administrator is not sure how to locate the user’s sessions on the system,
as well as stopping all UNIX processing, TSO/E processing, and batch processing.
8.1.5.2 Resource management
RACF makes access decisions based on information stored in profiles or in the metadata
associated with z/OS UNIX objects. RACF manages the following resource profiles:
 Data set profiles
 General resource profiles
General resource profiles apply to a number of resources defined as protected resources in
this Security Target. The structure of the profiles in RACF used to protect those resources is
identical, but the semantics of specific access rights is defined by the manager of the
resource and may therefore differ depending on the type of resource.
Profiles consists of a base segment and optionally a set of non-base segments. Fields within
non-base segments can be individually protected using the field-level access control
possibilities provided by RACF.
Field-level access control allows the control of READ and UPDATE access to individual fields
within a segment other than the base segment of a RACF profile. This access is based on
RACF profiles in the FIELD class. Profiles in this class have the structure of profile-
type.segment-name.field-name where profile-type is either the class name of a general
resource profile or one of DATASET, GROUP, or USER. Different profile classes/types can
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have different segments and the name of the segment that contains the field for which
access is controlled is specified as the second part of the profile. Different segments have
different fields identified by their name and the name of the field is the third part of the
profile controlling access to the field. The access control algorithm for access to general
resources is used also for the FIELD class.
Fields in segments are related to operands of RACF commands or the R_admin callable
service used to manage profiles and the purpose of field level access control is to provide a
mechanism that allows the definition of fine-grained access control to use those command
operands or list the content of individual fields. Table 18 in [RACF.SAG] provides a complete
list of the segment names and the fields within each of those segments that are subject to
field-level access control. The table also maps the field names to the command operands
that are used to update the fields. Note that use of those operands requires to have at least
UPDATE authority to the field through field-level access control unless the user has the
SPECIAL attribute {SM.4::SM.4-R12-RACFEAL5-FLA-1}. When profiles are listed, the user will
only get information about the content of fields in segments protected by field-level access
control, if he has at least READ access to the field, unless the user has the SPECIAL or
AUDITOR attribute {SM.4::SM.4-R12-RACFEAL5-FLA-2}.
In order use field-level access control, the FIELD class needs to be active and SETROPTS
RACLIST needs to be activated for the FIELD class. Otherwise only a user with the SPECIAL or
AUDITOR attribute has access to fields {SM.4::SM.4-R12-RACFEAL5-FLA-3}.
When the FIELD class is active and SETROPTS RACLIST is activated for the FIELD class, users
with the SPECIAL or AUDITOR attribute can list all fields regardless of the access definition in
the profile protecting access to the field {SM.4::SM.4-R12-RACFEAL5-FLA-4.
To allow users to read or update fields in their own user profile protected by field-level
access control a userid of &RACUID can be specified in the PERMIT command for the profiles
in the FIELD class related to the fields in profiles of type USER {SM.4::SM.4-R12-RACFEAL5-
FLA-5}. This does not allow this user access to those fields in the user profiles of other users
{SM.4::SM.4-R12-RACFEAL5-FLA-6}.
For information on z/OS UNIX objects see z/OS UNIX file system resources.
Additionally, the LDAP server makes access decisions based on information stored in the
LDBM database. For information on LDBM resources see LDAP LDBM Users.
Data set profiles
A data set profile within RACF contains (among other data not relevant for the security
functions defined in this Security Target) the following:
Name Description
Profile name Name of the data set profile
GENERIC, MODEL,
or TAPE
Indicates if it is a generic, a model or a tape data set profile
OWNER Owner of the data set profile
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Name Description
NOTIFY The TSO user who is to be notified whenever RACF uses this profile to
deny access to a data set
UACC The universal access authority for the data set or data sets protected
by the profile
AUDIT The type of auditing to be performed for the data set or data sets
protected by the profile
CATEGORY The security categories to be assigned to the data set or data sets
protected by the profile
SECLABEL The security label of the data set or data sets protected by the profile
(evaluated in Labeled Security Mode only)
SECLEVEL The security level of the data set or data sets protected by the profile
(evaluated in Labeled Security Mode only)
ERASE A setting that indicates whether the data set or data sets protected by
the profile are to be erased when they are scratched
UNIT The unit type on which the data set resides (for discrete profiles only)
VOLUME The volume on which the data set resides (for discrete profiles only)
Associated with those profiles is the access control list (ACL) for the profile. Each ACL entry
defines the access rights of a user or a group with respect to the resource protected by the
profile.
Attributes within an ACL entry are:
 access type (none, execute, read, update, control, alter)
 user IDs and group IDs allowed for the access type
 conditions of access (among other):
o WHEN(CONSOLE( console-id ...))
Modifies the access authority. Specifies that the identified users or groups have the specified
access authority when executing commands originating from the specified system console
o WHEN(JESINPUT( device-name ...))
Modifies the access authority. Specifies that the identified users or groups have the specified
access authority when entering the system through the specified JES input device
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o WHEN(PROGRAM( program-name...))
Modifies the access authority. Specifies that the identified users or groups have the specified
access authority when executing the specified program
o WHEN(TERMINAL( terminal-id ...))
Modifies the access authority. Specifies that the identified users or groups have the specified
access authority when logged on to the specified terminal
General resource profiles
Other protected resources defined in this Security Target (except the z/OS UNIX file system
objects and z/OS UNIX IPC objects) are protected by general resource profiles that contains
the resource class and the resource attributes. As with profiles for z/OS data sets, an access
control list with entries defining the access types for individual users and / or groups can be
defined for each such resource profile. The semantics of the individual access rights are
defined by the resource manager responsible for the management of the resources
protected by such a profile. Different resource classes may have different resource
managers responsible for the protection and management of the resources within the class.
The structure of a general resource profile is defined in the following table (omitting fields
that are not relevant for the Security Policy as defined in this Security Target:
Name Description
Class name Name of the resource class the profile belongs to
Profile name Name of the generic resource profile
OWNER( user ID or
groupname)
The owner of the profile
NOTIFY The user who is to be notified whenever RACF uses this profile to
deny access to a resource
UACC The universal access authority for the resource or resources protected
by the profile
AUDIT The type of auditing to be performed for the resource or resources
protected by the profile
FROM The name of a profile that is to be used as a model
FCLASS The class of the model profile
FGENERIC A setting that indicates that the model profile name is to be treated
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Name Description
as a generic name
FVOLUME The volume that is to be used to locate the model profile
CATEGORY The security categories to be assigned to the resource or resources
protected by the profile (evaluated in Labeled Security Mode only)
SECLABEL The security label of the resource or resources protected by the
profile (evaluated in Labeled Security Mode only)
SECLEVEL The security level of the resource or resources protected by the
profile (evaluated in Labeled Security Mode only)
LEVEL An installation-defined level
SINGLEDSN The tape volume protected by this profile can contain only one data
set (TAPEVOL class only)
TIMEZONE The time zone in which a terminal resides (TERMINAL class only)
TVTOC A setting that specifies that RACF is to create a tape volume table of
contents (TVTOC) when a user creates the first output data set on the
tape volume (TAPEVOL class only)
WHEN The times when the terminal or terminals protected by the profile can
be used to access the system (TERMINAL class only)
z/OS UNIX file system resources
z/OS UNIX file system resources are not protected by RACF profiles but by permission bits
and extended attributes stored in the z/OS UNIX file system. The evaluated configuration
supports two different z/OS UNIX file system types: zFS and HFS. A file system for both file
system types is always implemented in a single z/OS data set.
In the case of zFS the extended attributes also contain the security label (evaluated in
Labeled Security Mode only); therefore, a zFS file system can have different security labels
associated with different files. If varying security labels are to be used within one zFS file
system, the dataset containing the zFS file system must be created with the SYSMULTI
security label. After creation of the file system, the security label of the dataset must then
be set to SYSHIGH.
In the case of HFS, the extended attributes do not contain a security label and therefore in
Labeled Security Mode a HFS file system must be contained in a z/OS data set with a defined
security label. All z/OS UNIX files in this HFS will then automatically inherit the security label
of the hosting z/OS data set.
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See DAC for UNIX objects for details of the access control strategy for z/OS UNIX file system
objects.
LDAP LDBM resources
The LDAP administrator can configure some LDAP resources as requiring user authentication
prior to access, and others (representing public data which anyone should be able to access)
as not requiring authentication.
Additionally, the LDAP server maintains the following attributes for LDBM data objects, using
them in making access decisions. The TOE controls access to all directory entry objects
based on the following security attributes:
 Entry Owner Information:
o entryOwner: defines entry owner.
o ownerPropagate: indicates whether to propagate the ownership of the entry to
all descendant entries, until another entry with ownerPropagate is found.
 Access Control Attributes(ACA):
o aclEntry: defines the access control information.
o aclPropagate: indicates whether to propagate access control information of
the entry to all descendant entries, until another entry with aclPropagate is
found.
RACF General Resource classes
For the evaluation the protection of the following classes are considered:
CFIELD
Allows definition of fields in the CSDATA segment of USER and GROUP profiles
{SM.1::SM.2-R10-RACF-1}
CONSOLE
Controlling access to operator consoles. Also, conditional access to other resources for
commands originating from an operator console. {SM.2::SM.2.1}
CRYPTOZ
Controls access to PKCS#11 cryptographic tokens in the ICSF TKDS. {SM.2::SM.2-R9-
CRYPTOZ}
DASDVOL
DASD volumes. See also the GDASDVOL class. {SM.2::SM.2.2}
DEVICES
Used to control access to unit record devices, teleprocessing or communication
devices, and graphic devices. {SM.2::SM.2.3}
DIGTCERT
Used to register x.509v3 digital certificates in the RACF database.
DIGTCRIT
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Used to define additional mapping criteria for the interpretation of x.509v3 digital
certificates presented by clients when the certificates are not specifically registered in
the RACF database, and to assign a RACF user ID to the client’s session as part of the
client authentication process.
DIGTNMAP
Used to define the primary mapping rules for the interpretation of x.509v3 digital
certificates presented by clients when the certificates are not specifically registered in
the RACF database, and to assign a RACF user ID to the client’s session as part of the
client authentication process.
DIGTRING
Implements key rings for servers or users in the RACF database, holding information
about allowable Certificate Authority (CA) certificates and private keys for locally
defined personal certificates and local signing certificates.
DIRAUTH (used in Labeled Security Mode only)
This class ensures that security label authorization checking is done when a user
receives a message sent through the TPUT macro or the TSO SEND, or LISTBC
commands. Profiles are not allowed in this class. {SM.2::SM.2.4}
FACILITY
This class is used by various components of the TOE to manage specific privileges that
could be assigned to users such that they do not need the SPECIAL attribute or the
z/OS UNIX superuser privilege. Only a few profiles in this class are relevant for the
claims in this Security Target. Access to the relevant profiles in this class is covered by
individual claims for those profiles when appropriate..
GDASDVOL
Grouping class for DASDVOL {SM.2::SM.2-R8-RACF-GDASDVOL}
GLOBAL
Global access checking table entry. Provides the ability for fast access check for user
that don’t have the RESTRICTED attribute. Can be used for defined resource classes
only. Must be used to allow READ access to resources classified as SYSLOW only.
{SM.2::SM.2.5}
GTERMINL
Resource group class for TERMINAL class. {SM.2::SM.2.6}
GXFACILI
Grouping class for XFACILIT {SM.2::SM.2-R8-RACF-GXFACILI}
IDIDMAP
Class to provide mappinginformation from a distributed identity to a local RACF user ID
{SM.2::SM.2-R12-RACF-IDIDMAP}
JESINPUT
Port of entry class to control which JES2 input devices a user can use to submit batch
work to the system. {SM.2::SM.2.7}
JESJOBS
Controlling the submission and cancellation of jobs by job name. {SM.2::SM.2.8}
JESSPOOL
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Controlling access to job data sets on the JES spool (that is, SYSIN and SYSOUT data
sets). {SM.2::SM.2.9}
KERBLINK
Used to map user identities of local and foreign user IDs {SM.2::SM.2-R8-KERBLINK}
LOGSTRM
Used to control access to system logger resources, such as log streams and the
coupling facility structures associated with them {SM.2::SM.2-R9-LOGGER-LOGSTRM}
NODES
Controls the following on MVS systems:
 Whether jobs are allowed to enter the system from other JES2 nodes
{SM.2::SM.2.10}
 Whether jobs that enter the system from other nodes have to pass user identification
and password verification checks associated with JES/NJE {SM.2::SM.2.11}
OPERCMDS
Controls who can issue operator commands (for example, JES and MVS, and operator
commands). {SM.2::SM.2.12}
PROGRAM
Controlled programs (load modules). {SM.2::SM.2.13}
PSFMPL
Used by PSF to perform security functions for printing, such as separator page labeling,
data page labeling, and enforcement of the user printable area. {SM.2::SM.2.14}
PTKTDATA
Used to configure PassTicket processing {SM.2::SM.2-R8-PTKTDATA}
RDATALIB
Used to peform authorization checking for the R_datalib callable service {SM.2::SM.2-
R9-RDATALIB}
REALM
Used to define local and foreign Kerberos realms {SM.2::SM.2-R8-REALM}
SDSF
Controls the use of authorized commands in the System Display and Search Facility
(SDSF). {SM.2::SM.2.15}
SECDATA (used in Labeled Security Mode only)
Security classification of users and data (security levels and security categories).
{SM.2::SM.2.16}
SECLABEL (used in Labeled Security Mode only)
If security labels are used, and, if so, their definitions. {SM.2::SM.2.17}
SERVAUTH
Contains profiles that are used by servers to check a client’s authorization to use the
server or to use resources managed by the server. {SM.2::SM.2.18}
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SERVER
Controlling the server’s ability to register with the daemon. {SM.2::SM.2.19}
SMESSAGE
Controlling to which users a user can send messages (TSO only). {SM.2::SM.2.20}
STARTED
Used in preference to the started procedures table to assign an identity during the
processing of an MVS START command. Part of the Identification of STCs.
{SM.2::SM.2.21}
TAPEVOL
Tape volumes. {SM.2::SM.2.22}
TERMINAL
Terminals (TSO). {SM.2::SM.2.23}
TSOPROC
TSO logon procedures. {SM.2::SM.2.24}
UNIXPRIV
Contains profiles that are used to grant z/OS UNIX privileges. {SM.2::SM.2.25}
VTAMAPPL
Controlling who can open ACBs from non-APF authorized programs. This prevents
programs from counterfeiting login screens. {SM.2::SM.2.26}
WRITER
Controlling the use of JES writers. {SM.2::SM.2.27}
XFACILIT
Analogous to the FACILITY class, but supporting longer resource and profile names
(246 characters vs 39 for FACILITY) {SM.2::SM.2-R8-XFACILIT}
8.1.5.3 RACF configuration and management
Configuring RACF with the SETROPTS command
The SPECIAL and AUDITOR roles can define system wide-options of RACF with the SETROPTS
command. This command can be used (among other actions) to:
 Choose the resource classes that RACF is to protect. {SM.3::SM.3.1}
 Set the universal access authority (UACC) for otherwise undefined terminals.
{SM.3::SM.3.2}
 Specify logging of certain RACF commands and events. {SM.3::SM.3.3}
 Enable or disable list-of-groups access checking. {SM.3::SM.3.4}
 Display options currently in effect. {SM.3::SM.3.5}
 Enable generic profile checking for all active classes. {SM.3::SM.3.6}
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 Establish password syntax rules. {SM.3::SM.3.7}
 Activate password processing for checking previous passwords, limit invalid password
attempts, and warn of password expiration. {SM.3::SM.3.8}
 Control global access checking for selected individual resources or generic names
with selected generalized access rules. {SM.3::SM.3.9}
 Set the passwords for authorizing use of the RVARY command. {SM.3::SM.3.10}
 Initiate refreshing of in-storage generic profile lists and global access checking tables.
{SM.3::SM.3.11}
 Enable or disable shared profiles through RACLIST processing for general resources.
{SM.3::SM.3.12}
 Activate auditing of access attempts to RACF-protected resources based on
installation-defined security levels. {SM.3::SM.3.13}
 Activate enhanced generic naming. {SM.3::SM.3.14}
 Activate profile modeling for GDG, group, and user data sets. {SM.3::SM.3.15}
 Activate protection for data sets with single-level names. {SM.3::SM.3.16}
 Control logging of real data set names. {SM.3::SM.3.17}
 Control the job entry subsystem (JES) options implemented in RACF. {SM.3::SM.3.18}
 Activate tape data set protection. {SM.3::SM.3.19}
 Enable protection of data sets by default (PROTECTALL(FAILURES)). {SM.3::SM.3.20}
 Enable the erasure of scratched DASD data sets. {SM.3::SM.3.21}
 Activate program control. {SM.3::SM.3.22}
 Control whether a profile creator’s user ID is automatically added to the profile’s
access list. {SM.3::SM.3.23}
Some administration activities can be delegated to user with other roles. See the definition
of those roles for the administrative options that can be set or defined by those roles.
To operate in correspondence with the requirements in this Security Target, the system
administrator needs to configure RACF (using the SETROPTS command) with the following
options: CATDSNS(FAILURES), NOCOMPATMODE, ERASE(ALL), GENERIC(*),
PROTECTALL(FAILURES), CLASSACT (TEMPDSN), JES(BATCHALLRACF). In Labeled Security
Mode the following options need to be set in addition: MLACTIVE(FAILURES),
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MLFSOBJ(ACTIVE), MLIPCOBJ(ACTIVE), MLS(FAILURES), MLSTABLE, SECLABELCONTROL.
{SM.3::SM.3.24}. Additional parameter for the PASSWORD operand need to be set to define
the password policy. See RACF Passwords and Password Phrases for more information.
RACF commands
The administration of RACF is performed by a set of commands. Users need the required
authorities or roles to issue those commands or specific parameter of those commands. The
main RACF commands are:
 ADDGROUP, ALTGROUP, DELGROUP
Commands to define a new group profile, modify an existing group profile or delete a group
profile {SM.3::SM.3.25}
 ADDUSER, ALTUSER, DELUSER
Commands to define a new user profile, modify an existing user profile or delete a user
profile {SM.3::SM.3.26}
 ADDSD, ALTDSD, DELDSD
Commands to define a new z/OS data set profile, modify an existing z/OS data set profile or
delete an existing z/OS data set profile {SM.3::SM.3.27}
 CONNECT, REMOVE
Command to connect a user to or remove a user from a group {SM.3::SM.3.28}
 LISTGROUP, LISTUSER, LISTDSD
Commands to list user, group or z/OS data set profiles {SM.3::SM.3.29}
 RDEFINE, RALTER, RDELETE
Commands to define, modify or delete a general resource profile {SM.3::SM.3.30}
 RLIST
Command to list a general resource profile {SM.3::SM.3.31}
 PASSWORD
Command to specify a user’s password {SM.3::SM.3.32}
 PHRASE
Command to specify a user’s password phrase {SM.3::SM.3-R10-RACF-1}
 PERMIT
Command to maintain the access list of a resource profile {SM.3::SM.3.33}
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 RACDCERT
Command to maintain x.509v3 digital certificates, certificate mapping filters, certificate
mapping criteria, and key rings in the RACF database.
 RACMAP
Command to establish mappings between distributed user identities and local RACF user IDs
{SM.3::SM.3-R12-RACF-2}.
 SETROPTS
Command to set specific RACF options (see section above for details) {SM.3::SM.3.34}
There are the following options how a RACF command can be issued:
• as a TSO command
• as an operator command
• with command direction (command can be directed to run under the authority of a
user ID on a remote node, or the same node using the AT operand. Use of this
operand is usually restricted as indicated in the table below). [Note: This method is
part of the RACF Remote Sharing Facility (RRSF) which is not a part of this evaluation,
and will not be considered further.]
• with automatic command direction (activated using the SET AUTODIRECT command.
Use is restricted by RACF profiles as for command direction)[Note: This method is
part of the RACF Remote Sharing Facility (RRSF) which is not a part of this evaluation,
and will not be considered further.]
• from the RACF parameter library
• via the R_admin callable service
Not all commands can be issued in all options. For example some commands can not be
used as TSO commands, and some can not be used as operator commands.
{SM.3::SM.3-R12-RACFEAL5-30} For commands (except RVARY) that can be issued as either a
TSO command or as an operator command, the following security requirements apply in addition
to any specified by the commands themselves:
• The command issuer must be logged on to the console.
• If the OPERCMDS class is active and SETR RACLISTed then the command issuer must
have READ authority to the OPERCMDS profile protecting the command, if one exists:
Command Name OPERCMDS Resource name
ADDGROUP Subsystem-name.ADDGROUP
(Note: for all the RACF TSO commands,
when issued as an operator command
the OPERCMDS resource name uses the
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Command Name OPERCMDS Resource name
full command name, even if the user
issued the command using an
abbreviation such as AG)
ADDSD Subsystem-name.ADDSD
ADDUSER Subsystem-name.ADDUSER
ALTDSD Subsystem-name.ALTDSD
ALTGROUP Subsystem-name.ALTGROUP
ALTUSER Subsystem-name.ALTUSER
CONNECT Subsystem-name.CONNECT
DELDSD Subsystem-name.DELDSD
DELGROUP Subsystem-name.DELGROUP
DELUSER Subsystem-name.DELUSER
LISTDSD Subsystem-name.LISTDSD
LISTGRP Subsystem-name.LISTGRP
LISTUSER Subsystem-name.LISTUSER
PASSWORD Subsystem-name.PASSWORD
PHRASE Subsystem-name.PASSWORD
PERMIT Subsystem-name.PERMIT
RALTER Subsystem-name.RALTER
RDEFINE Subsystem-name.RDEFINE
RDELETE Subsystem-name.RDELETE
REMOVE Subsystem-name.REMOVE
RLIST Subsystem-name.RLIST
SEARCH Subsystem-name.SEARCH
SETROPTS Subsystem-name.SETROPTS
(Note: READ authority is required to
issue SETROPTS LIST, but UPDATE is
required if any other operands are
specified.)
{SM.3::SM.3-R12-RACFEAL5-31} For commands that can be issued as operator commands but
not as TSO commands, the following security requirements apply:
• If you are logged on to the console, and the command is protected by an OPERCMDS
profile, then you must have READ authority to that profile:
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Command Name OPERCMDS Resource name
DISPLAY Subsystem-name.DISPLAY.SIGNON
Note: No OPERCMDS authority check
is performed when this command is
issued from a RACF parameter library
member.
RESTART Subsystem-name.RESTART
SET subsystem-name.SET.AUTOAPPL
subsystem-name.SET.AUTODIRECT
subsystem-name.SET.AUTOPWD
subsystem-name.SET.INCLUDE
subsystem-name.SET.JESNODE
subsystem-name.SET.LIST
subsystem-name.SET.PWSYNC
subsystem-name.SET.TRACE
Note: No OPERCMDS authority check
is performed when this command is
issued from a RACF parameter library
member.
SIGNOFF Subsystem-name.SIGNOFF
Note: No OPERCMDS authority check
is performed when this command is
issued from a RACF parameter library
member.
STOP Subsystem-name.STOP
TARGET subsystem-
name.TARGET.DESCRIPTION
subsystem-name.TARGET.LIST
subsystem-name.TARGET.LOCAL
subsystem-name.TARGET.NODE
subsystem-name.TARGET.OPERATIVE
Note: TARGET.OPERATIVE also
protects the DELETE and DORMANT
operands.
subsystem-name.TARGET.PREFIX
subsystem-name.TARGET.PROTOCOL
subsystem-name.TARGET.PURGE
subsystem-name.TARGET.WDSQUAL
subsystem-
name.TARGET.WORKSPACE
Note: No OPERCMDS authority check
is performed when this command is
issued from a RACF parameter library
member.
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•If you are not logged on to the console, or the command is not protected by an
OPERCMDS profile, then (except for the DISPLAY command) you must issue the
command from a console with MASTER or SYSTEM authority.
Administrators can also use the LDAP SDBM backend {SM.3::SM.3-R9-LDAP-1} or the Java
JSEC interfaces {SM.3::SM.3-R9-JSEC-1} to issue the RACF commands ADDUSER, ALTUSER,
DELUSER, LISTUSER, ADDGROUP, ALTGROUP, DELGROUP, LISTGRP, CONNECT, and REMOVE.
Additionally, administrators can use the LDAP SDBM backend to issue RDEFINE, RDELETE,
RALTER, RLIST, and SETROPTS commands for class-related options {SM.3::SM.3-R11-LDAP-
2}.
Command Authorities required for use
ADDGROUP {SM.3::SM.3-R12-RACFEAL5-1} General:
• SPECIAL or
• group-SPECIAL and the superior group is within the scope
of group-SPECIAL authority, or
• owner of the superior group, or
• JOIN authority to the superior group
Special parameter authorization:
• SPECIAL or UPDATE authority via field-level access control
to add segments to a group’s profile
•
• For use of the SHARED keyword: SPECIAL or READ
authority to the SHARED.IDS resource in the UNIXPRIV
class
ADDSD {SM.3::SM.3-R12-RACFEAL5-2} The level of authority required to
use the ADDSD command and the types of profiles the caller can
define are:
To protect a user data set with RACF, one of the following must
be true:
• The high-level qualifier of the data set name (or the
qualifier supplied by the RACF naming conventions table)
must match the caller’s user ID, or
• SPECIAL, or
• The user ID for the data set profile must be within the
scope of a group in which the caller has the group-
SPECIAL attribute.
To protect a group data set with RACF, one of the following must
be true:
• CREATE authority in the group, or
• SPECIAL, or
• OPERATIONS attribute and not be connected to the group,
or
• The data set profile must be within the scope of the group
in which the caller has the group-SPECIAL attribute.
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Command Authorities required for use
• The data set profile must be within the scope of the group
in which the caller has the group-OPERATIONS attribute,
and he must not be connected to the group.
Special parameter authorization:
•
•
• To assign a security category to a profile, you must have
the SPECIAL attribute or have the category in your user
profile.
• To assign a security level to a profile, you must have the
SPECIAL attribute or, in your own profile, a security level
that is equal to or greater than the security level you are
defining.
• To assign a security label to a profile, you must have the
SPECIAL attribute or (when SETROPTS SECLABELCONTROL
is not active) READ authority to the security label profile.
• To add non-base segments, SPECIAL or UPDATE authority
via field-level access control.
• To add a discrete profile for a VSAM data set already
RACF-protected by a generic profile, you must have
ALTER access authority to the catalog or to the data set
through the generic profile.
• To specify a model data set profile (using, as required,
FROM, FCLASS, FGENERIC, and FVOLUME), you must have
sufficient authority over the model profile (the from
profile). RACF makes the following checks until one of the
conditions is met:
• You have the SPECIAL attribute.
• The from profile is within the scope of a group in
which you have the group-SPECIAL attribute.
• You are the owner of the from profile.
• The high-level qualifier of the profile name (or the
qualifier supplied by the RACF naming conventions
table) is your user ID.
• For a discrete profile, you are on the access list in
the from profile with ALTER authority. (If you have
any lower level of authority, you cannot use the
profile as a model.)
• For a discrete profile, your current connect group
(or, if list-of-groups checking is active, any group to
which you are connected) is on the access list in
the from profile with ALTER authority.
• For a discrete profile, the UACC is ALTER.
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Command Authorities required for use
ADDUSER {SM.3::SM.3-R12-RACFEAL5-3} General:
• SPECIAL or
• CLAUTH for the USER class and one of the following is
true:
◦ The caller is the owner of the default group specified
◦ The caller has JOIN authority in the default group
specified
◦ The default group specified is within the scope of
agroup where the caller has group-SPECIAL
Special parameter authorization:
• SPECIAL to give the new user the OPERATIONS, SPECIAL
or AUDITOR attribute
• SPECIAL to assign a security category to a profile or the
category must be in the caller’s user profile
• SPECIAL to assign a security level to a profile or the
security level in the caller’s profile is equal or greater than
the security level assigned to the new user
• When defining information within a segment other than
the base segment:
◦ SPECIAL, or
◦ UPDATE authority to the desired field through field-
level access control
• For use of the SHARED keyword: SPECIAL or READ
authority to the SHARED.IDS resource in the UNIXPRIV
class
ALTDSD {SM.3::SM.3-R12-RACFEAL5-4} The level of authority required to
use the ALTDSD command and the types of profiles the caller
can define are:
To protect a user data set with RACF, one of the following must
be true:
• The high-level qualifier of the data set name (or the
qualifier supplied by the RACF naming conventions table )
must match the caller’s user ID, or
• SPECIAL, or
• The user ID for the data set profile must be within the
scope of a group in which the caller has the group-
SPECIAL attribute.
• The caller is the owner of the profile
• For a discrete profile: the caller has ALTER authority to
the profile or the caller’s current connect group (or, if list-
of-groups checking is active) has ALTER authority
Special parameter authorization:
• For use of the GLOBALAUDIT keyword: AUDITOR or the
data set profile is within the scope of a group in which the
caller has the group-AUDITOR attribute
• For access to the DFP or TME segment: field-level access
authority to those segments
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Command Authorities required for use
• SPECIAL to assign a security label, or when SETR
SECLABELCONTROL is not active, READ authority to the
specified SECLABEL.
• SPECIAL to assign a security category to a profile or
remove a security category from a profile, or the category
must be in the caller’s user profile.
• SPECIAL to assign a security level to a profile or the
security level in the caller’s profile is equal or greater than
the security level assigned to the new user
ALTGROUP {SM.3::SM.3-R12-RACFEAL5-5} General:
• To issue the command,, except as specified below:
• SPECIAL
• The group profile is within the scope of a group in
which you have the group-SPECIAL attribute
• You are the current owner of the group.
Special parameter authorization:
• To change the superior group of a group:
• SPECIAL or
• group-SPECIAL and the current and new superior
group is within the scope of group-SPECIAL
authority, or
• owner of the current and new superior group, or
• JOIN authority to the current and new superior
group
• A combination of group-SPECIAL, owner or JOIN
authority where one of those applies for the
current and one of those applies for the new
superior group
• SPECIAL or permission through field-level access checking
in order to add, delete, or alter segments of a group’s
profile
• For use of the SHARED keyword: SPECIAL or READ
authority to the SHARED.IDS resource in the UNIXPRIV
class
ALTUSER {SM.3::SM.3-R12-RACFEAL5-6} General:
• SPECIAL (allows use of all operands except
UAUDIT/NOUAUDIT)
Special parameter authorization:
• If the owner of the user profile is within the scope of a
group in which the group-SPECIAL attribute, he can use
all of the operands except SPECIAL, AUDITOR,
OPERATIONS, NOEXPIRED and UAUDIT/NOUAUDIT.
• The owner of the user’s profile can use any of the
following operands for user-related attributes:
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◦ ADSP | NOADSP
◦ DATA | NODATA
◦ DFLTGRP
◦ GRPACC | NOGRPACC
◦ MODEL | NOMODEL
◦ NAME
◦ OIDCARD | NOOIDCARD
◦ OWNER
◦ PASSWORD | NOPASSWORD
◦ PHRASE | NOPHRASE
◦ RESTRICTED | NORESTRICTED
◦ RESUME | NORESUME
◦ REVOKE | NOREVOKE
◦ WHEN
• Each user can change his or her name field, default group or
model data set profile name (using the NAME, DFLTGRP, or
MODEL operand, respectively).
• You can use the GROUP, AUTHORITY, and UACC operands
for group-related user attributes if you have JOIN or
CONNECT authority, if the group profile is within the
scope of a group in which you have the group-SPECIAL
attribute, or if you are the owner of the specified group.
• To specify the AUDITOR/NOAUDITOR, SPECIAL/NOSPECIAL,
and OPERATIONS/NOOPERATIONS operands as system-
wide user attributes, the caller must have the SPECIAL
attribute.
• To specify the UAUDIT/NOUAUDIT operand, either the
caller must have the AUDITOR attribute, or the user
profile must be within the scope of a group in which the
caller has the group-AUDITOR attribute.
• The CLAUTH and NOCLAUTH operands can be specified if
the caller is the owner of the user’s profile and has the
CLAUTH attribute for the class to be added or deleted.
• To assign a security category to a profile, or to delete a category
from a profile, one of the following must be true:
• If the user profile is within the scope of a group in which
you have the group-SPECIAL attribute, or if you are the
owner of the specified user, the category you are adding
or deleting must be in your user profile.
• You have the SPECIAL attribute.
• To assign a security level to a profile, or to delete a security level
from a profile, one of the following must be true:
• If the user profile is within the scope of a group in which
you have the group-SPECIAL attribute, or if you are the
owner of the specified user, the security level in your user
profile must be equal to or greater than the security level
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you are assigning or deleting.
• You have the SPECIAL attribute.
• To change information within a segment other than the
base segment, the caller must have one of the following:
◦ The SPECIAL attribute
◦ At least UPDATE authority to the desired field within
the segment through field-level access control.
• To reset passwords and password phrases or to resume
user IDs, the caller must have at least one of the following
authorizations:
◦ SPECIAL.
◦ group-SPECIAL authority over the user profile.
◦ The caller is the OWNER of the user profile.
◦ The caller has sufficient access to the
IRR.PASSWORD.RESET resource in the FACILITY class.
◦ The caller has sufficient access to an appropriate
resource in the FACILITY class
(IRR.PWRESET.OWNER.owner or
IRR.PWRESET.TREE.owner), and both of the following
conditions are also true:
▪ The other user does not have the SPECIAL,
OPERATIONS, AUDITOR, or PROTECTED attribute.
▪ The caller is not excluded from altering the user by
the IRR.PWRESET.EXCLUDE.excluded-user
resource in the FACILITY class.
• When the caller’s reset and resume authority is through
access to the IRR.PASSWORD.RESET resource, the
IRR.PWRESET.OWNER.owner resource, or the
IRR.PWRESET.TREE.owner resource, the following
requirements apply:
◦ If the caller has READ access, he can:
▪ Use the PASSWORD operand to reset a password
(to an expired password) for a user who does not
have the SPECIAL, OPERATIONS, AUDITOR, or
PROTECTED attribute.
▪ Use the PHRASE operand to reset a password
phrase (to an expired password phrase) for a user
with an assigned password phrase who does not
have the SPECIAL, OPERATIONS, AUDITOR, or
PROTECTED attribute. Note: The caller cannot use
the PHRASE operand to add a password phrase for
a user who does not have one.
▪ Use the RESUME operand, without specifying a
date, for a user who does not have the SPECIAL,
OPERATIONS, AUDITOR, or PROTECTED attribute.
◦ If the caller has UPDATE access, he can:
▪ Use the PASSWORD, PHRASE, and RESUME
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operands as noted for READ access.
▪ Use the NOEXPIRED operand (with PASSWORD or
PHRASE) for a user who does not have the
SPECIAL, OPERATIONS, AUDITOR, or PROTECTED
attribute.
◦ If the caller has CONTROL access, he can:
▪ Use the PASSWORD, PHRASE, RESUME, and
NOEXPIRED operands as noted for READ and
UPDATE access.
▪ Reset the password or password phrase within the
minimum change interval for a user who does not
have the SPECIAL, OPERATIONS, AUDITOR, or
PROTECTED attribute.
• For use of the SHARED keyword: SPECIAL or READ
authority to the SHARED.IDS resource in the UNIXPRIV
class
CONNECT {SM.3::SM.3-R12-RACFEAL5-7} General:
• SPECIAL, or
• Group-SPECIAL in the group
• Ownership of the group
• JOIN authority in the group
• CONNECT authority in the group
• A caller can not give a higher level of authority in the
group than he has himself.
•
DELDSD {SM.3::SM.3-R12-RACFEAL5-8} General:
• SPECIAL, or
• The data set profile is within the scope of a group in which
the caller has the group-SPECIAL attribute, or
• The high-level qualifier of the profile name (or the
qualifier supplied by the naming convention table) is the
caller’s user ID, or
• The caller is the owner of the profile
• For a discrete profile: the caller is on the access list with
ALTER authority, or
• For a discrete profile, the caller’s group or one of the
caller’s groups (if checking list of groups is active) is on
the access list and has ALTER authority.
• For a discrete profile, the universal access authority is
ALTER.
DELGROUP {SM.3::SM.3-R12-RACFEAL5-9} General:
• SPECIAL, or
• The group to be deleted is within the scope of a group
where the caller has the group-SPECIAL in the group, or
• The caller is the Owner of the group to be deleted, or
• The caller is the Owner of a superior group of the group to
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be deleted
• JOIN authority in the superior group
DELUSER {SM.3::SM.3-R12-RACFEAL5-10} General:
• SPECIAL, or
• Group-SPECIAL for the group where the user profile to be
deleted is within the scope of the group, or
• Ownership of the user profile
Other:
• A user profile that has a distributed identity filter
associated with it can only be deleted after the distributed
identity filter has been deleted.
DISPLAY {SM.3::SM.3-R12-RACFEAL5-25} None (can be used an operator
command only. RACF allows restricting the use of specific
operator commands to defined users).
LISTDSD {SM.3::SM.3-R12-RACFEAL5-11} For listing the RACF segment of
a data set profile:
• SPECIAL, or
• The data set profile is within the scope of a group in which
the caller has the group-SPECIAL attribute, or
• OPERATIONS, or
• The data set profile is within the scope of a group in which
the caller has the group-OPERATIONS attribute, or
• AUDITOR, or
• The data set profile is within the scope of a group in which
the caller has the group-AUDITOR attribute, or
• The high-level qualifier of the profile name (or the
qualifier supplied by the naming convention table) is the
caller’s user ID, or
• The caller is the owner of the profile
• The caller is on the access list with READ authority, or
• The caller’s group or one of the caller’s groups (if
checking list of groups is active) is on the access list and
has READ authority, or
• The universal access authority is READ, or
• The caller has READ access for the profile name from the
GLOBAL ENTRY TABLE (if the table contains an entry for
the profile)
For listing the DFP or TME segment of a data set profile:
• SPECIAL, or
• AUDITOR, or
• READ authority to the desired field within the segment
through field-level access control.
Special parameter authorization:
• To specify the AUTHUSER operand to display the access
list for a profile, one of the following conditions must be
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met for each profile to be listed:
◦ SPECIAL, or
◦ The data set profile is within the scope of a group in
which the caller has the group-SPECIAL attribute, or
◦ OPERATIONS, or
◦ The data set profile is within the scope of a group in
which the caller has the group-OPERATIONS attribute,
or
◦ AUDITOR, or
◦ The data set profile is within the scope of a group in
which the caller has the group-AUDITOR attribute, or
◦ The high-level qualifier of the profile name (or the
qualifier supplied by the naming convention table) is
the caller’s user ID, or
◦ The caller is the owner of the profile
◦ The caller has ALTER access for the profile name from
the GLOBAL ENTRY TABLE (if this table contains an
entry for the profile).
◦ For a discrete profile, the caller is on the profile’s
access list with ALTER authority.
◦ For a discrete profile, the caller’s current connect
group (or, if list-of-groups checking is active, any
group to which the caller is connected) is in the access
list and has ALTER authority.
◦ For a discrete profile, the universal access authority is
ALTER.
Other:
• To display the type of access attempts (as specified by
the GLOBALAUDIT operand on the ALTDSD command)
that are being logged on the SMF data set, either the
caller must have the AUDITOR attribute or the profile
must be within the scope of a group in which the caller
has the group-AUDITOR attribute.
LISTGRP {SM.3::SM.3-R12-RACFEAL5-12} For listing the RACF segment of
a group profile:
• SPECIAL, or
• AUDITOR, or
• For each group to be listed at least one of the following is
true:
◦ The caller has group-SPECIAL the group or the group
profile is within the scope of a group in which the
caller has the group-SPECIAL attribute, or
◦ The caller has group-AUDITOR for the group or the
group profile is within the scope of a group in which
the caller has the group-AUDITOR attribute, or
◦ The caller is the owner of the group, or
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◦ The caller has JOIN or CONNECT authority for the
group
For listing the other segments of a group profile:
• SPECIAL, or
• AUDITOR, or
• READ access to the desired field through field-level access
control
LISTUSER {SM.3::SM.3-R12-RACFEAL5-13} For listing the RACF segment of
a user profile:
• SPECIAL, or
• AUDITOR, or
• For each user to be listed at least one of the following is
true:
◦ the user profile is within the scope of a group in which
the caller has the group-SPECIAL attribute, or
◦ the user profile is within the scope of a group in which
the caller has the group-AUDITOR attribute, or
◦ The caller is the owner of the user profile, or
◦ The caller has READ access to the IRR.LISTUSER
resource in the FACILITY class and the user does not
have the SPECIAL, AUDITOR, or OPERATIONS attribute.
◦ The caller has READ access to an appropriate resource
(IRR.LU.OWNER.owner or IRR.LU.TREE.owner) in the
FACILITY class, and both of the following conditions
are also true:
▪ The user does not have the SPECIAL, AUDITOR, or
OPERATIONS attribute.
▪ The caller is not excluded from listing the user by
the IRR.LU.EXCLUDE.excluded-user resource in the
FACILITY class.
For listing other segments of a user profile:
• SPECIAL, or
• AUDITOR, or
• READ authority to the desired field within the segment
through field-level access checking
Other:
• If the caller has the group-SPECIAL or group-AUDITOR
attribute and the installation has assigned security levels
and security categories to user profiles, the caller must
have the following to be able to display the RACF segment
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of a user’s profile:
◦ A security level equal to, or greater than, that in the
user profile the caller is trying to display
◦ All security categories contained in the user profile the
caller is trying to display are contained in the caller’s
own user profile.
• The value of the UAUDIT/NOUAUDIT operand is only listed
if the authorization is given by the AUDITOR or group-
AUDITOR authorities.
PASSWORD {SM.3::SM.3-R12-RACFEAL5-14} General:
• To change a user’s password or password phrase or
change interval:
◦ The caller is the user himself, or
◦ SPECIAL, or
◦ the user’s profile is within the scope of a group in
which the caller has group-SPECIAL
• To reset another user’s password to the default value:
◦ The caller is the owner of the user’s profile
◦ SPECIAL, or
◦ the user’s profile is within the scope of a group in
which the caller has group-SPECIAL
PERMIT {SM.3::SM.3-R12-RACFEAL5-15} General:
• SPECIAL, or
• The profile is within the scope of a group in which the
caller has the group-SPECIAL attribute, or
• The caller is the owner of the resource, or
• For a discrete profile: the caller has ALTER authority
(either via the standard access list, or via group access or
via UACC)
• For profiles in the DATASET class: the high-level qualifier
of the profile name (or the qualifier supplied by the RACF
naming conventions table) is the caller’s user ID.
• For profiles in the FILE or DIRECTRY class: the second
qualifier of the profile name is the caller’s user ID.
PHRASE See PASSWORD
RACDCERT See separate table
RACMAP {SM.3::SM.3-R13-RACFEAL5-16} General:
• SPECIAL, or
• Sufficient authority to the IRR.IDIDMAP.function resource
in the FACILITY class, where function is MAP, DELMAP,
QUERY, or LISTMAP. READ authority is required for the
caller to create, delete, or list a distributed identity filter
for his own RACF user ID. UPDATE authority is required for
the caller to create, delete, or list a distributed identity
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filter for another RACF user ID.
RACPRIV {SM.3::SM.3-R12-RACFEAL5-17} General:
• READ access to the profile IRR.WRITEDOWN.BYUSER in
the FACILITY class.
RALTER {SM.3::SM.3-R12-RACFEAL5-18} General (with the exception of
the GLOBALAUDIT parameter):
• SPECIAL, or
• The profile is within the scope of a group in which the
caller has the group-SPECIAL attribute, or
• The caller is the owner of the profile, or
• For a discrete profile: the caller has ALTER authority
(either via the standard access list, or via group access or
via UACC)
• For profiles in the FILE or DIRECTRY class: the second
qualifier of the profile name is the caller’s user ID. (Note:
the FILE and DIRECTRY classes apply only in z/VM
systems, and will not be considered in this evaluation
even though the classes exist in RACF for z/OS.)
• To assign a security category to a profile, or to delete a
category from a profile, the caller must have the SPECIAL
attribute, or the category must be in the caller’s user
profile.
• To assign a security level to a profile, or to delete a
security level from a profile, the caller must have the
SPECIAL attribute, or, in his own profile, a security level
that is equal to or greater than the security level he is
assigning or deleting.
• To assign a security label, SPECIAL, or when SETROPTS
SECLABELCONTROL is not active, the caller must have
READ access to the security label profile.
Special parameter authorization:
• For defining a delegated resource (by specifying the
RACF-DELEGATED string in the APPLDATA of the profile),
when the profile has a SECLABEL and SETR
SECLBELCONTROL is active, SPECIAL
• For modifying information in segments other than the
base segment:
◦ SPECIAL, or
◦ UPDATE Access allowed by field-level access control
for the fields to be modified
• For use of the GLOBALAUDIT parameter:
◦ AUDITOR, or
◦ The profile is within the scope of a group for which the
caller has the group-AUDITOR attribute.
• For use of the ADDMEM parameter:
◦ For classes other than SECLABEL, PROGRAM,
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SECDATA, GLOBAL, RACFVARS, and NODES, if the
member resources are already RACF-protected by a
member class profile or as a member of a profile in
the same grouping class, one of the following must be
true:
▪ The caller has ALTER access authority to the
member, or
▪ The caller is the owner of the member resource, or
▪ The member resource is within the scope of a
group in which the caller has the group-SPECIAL
attribute, or
▪ The caller has the SPECIAL attribute.
◦ For classes other than SECLABEL, PROGRAM,
SECDATA, GLOBAL, RACFVARS, and NODES, if the
member resources are not RACF-protected (that is,
there is no profile defined for that member), one of the
following must be true:
▪ The caller has CLAUTH authority to define
resources in the member resource class.
▪ The caller has the SPECIAL attribute.
◦ To add a member to a profile in the RACFVARS or
NODES class, one of the following must be true:
▪ The caller has CLAUTH authority to define
resources in the specified class
▪ The caller has the SPECIAL attribute.
▪ The caller is the owner of the profile indicated by
profile-name.
▪ The caller has ALTER access authority to the
profile indicated by profile-name.
◦ To add a member to a profile in the PROGRAM or SECDATA
class, one of the following must be true:
▪ You have CLAUTH authority to define resources in the
specified class (for example, PROGRAM or SECDATA).
▪ You have the SPECIAL attribute.
◦ To add a member to a profile in the GLOBAL class
(other than the GLOBAL DATASET, GLOBAL DIRECTRY,
or GLOBAL FILE profile)
▪ If the profile resource-name is already RACF-
protected by a profile in class class-name:
• ALTER access authority to the profile resource-
name in class class-name, or
• The caller is the OWNER of the profile resource-
name, or
• The profile resource-name in class class-name
is within the scope of a group in which the
caller has the group-special attribute, or
• The caller has the SPECIAL attribute.
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▪ If the profile resource-name is not already RACF-
protected (that is, there is no profile defined for
that member in class class-name):
• The caller has CLAUTH authority to define
resources in the class class-name, or
• The caller has the SPECIAL attribute.
◦ To add a member to the GLOBAL DATASET profile, one
of the following must be true:
▪ The caller is the owner of the DATASET profile in
the GLOBAL class.
▪ The member is within the scope of a group in
which the caller has the group-SPECIAL attribute,
or the high-level qualifier of the member name is
the caller’s user ID.
▪ The caller has the SPECIAL attribute.
◦ To add a member to the GLOBAL DIRECTRY or GLOBAL
FILE profile, the caller must have the SPECIAL
attribute.
• For use of the DELMEM operand:
◦ If class-name is specified as GLOBAL or PROGRAM, the
rules for member are the same as given for ADDMEM.
If class-name is specified as SECDATA, member should
be a valid SECLEVEL name or category name.
• For use of the ADDVOL operand:
◦ SPECIAL, or
◦ CLAUTH attribute for the TAPEVOL resource class in
addition to the other authorization requirements for
using the RALTER command.
• For use of the GLOBALAUDIT operand:
◦ AUDITOR, or
◦ The resource profile must be within the scope of a
group in which the caller has the group-AUDITOR
attribute.
RDEFINE {SM.3::SM.3-R12-RACFEAL5-19} General (with the exception of
the GLOBALAUDIT parameter):
• SPECIAL, or
• If the caller has CLAUTH authority for the GLOBAL class,
and group-SPECIAL authority in a group, he can add
members whose high-level qualifier is the group name or
a user ID in the scope of the group. This applies only to
classes that are sensitive to high-level qualifiers, such as
DATASET.
• If the name to be defined is not already defined to RACF
as a member of a resource group and the caller is
defining a profile in a normal (non-member, non-grouping)
class, a member class, or a member of a grouping class,
he must have CLAUTH authority for the specified class.
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• If the resource to be defined is a discrete name already
defined to RACF as a member of a resource group, the
caller can define it as a resource to RACF if he has ALTER
authority, or if the resource group profile is within the
scope of a group in which he has the group-SPECIAL
attribute, or if he is the owner of the resource group
profile. If authority conflicts arise because the resource is
a member of more than one group and the user’s
authority in those groups differs, RACF resolves the
conflict by using the least restrictive authority.
• If the caller defines a profile in the FILE or DIRECTRY class,
one of the following must be true:
◦ The second qualifier of the profile name must match
the caller’s user ID
◦ The caller has the SPECIAL attribute
◦ The profile name must be within the scope of a group
in which the caller has the group-SPECIAL attribute.
(Note: the FILE and DIRECTRY classes apply only in
z/VM systems, and will not be considered in this
evaluation even though the classes exist in RACF for
z/OS.)
• If the caller does not have the SPECIAL attribute and the
SETROPTS GENERICOWNER option is in effect, and if an
existing generic profile protects the profile name the
caller is defining, he needs to own the less specific profile.
GENERICOWNER does not apply to the PROGRAM class.
• To assign a security category to a profile, the caller must
have the category in his user profile.
• To assign a security level to a profile, the caller’s own
profile must have a security level that is equal to or
greater than the security level he is defining.
• To assign a SECLABEL to the profile, the caller must have
READ access to the SECLABEL profile or, when SETROPTS
SECLABELCONTROL is in effect, the SPECIAL attribute.
• To define segments other than the base segment, the
caller must have the SPECIAL attribute or he must be
permitted to do so through field-level access checking.
Other:
• Only a SPECIAL user can define a delegated resource (by
specifying the RACF-DELEGATED string in the APPLDATA
of the profile protecting the resource) when the resource
has a SECLABEL and SETROPTS SECLABELCONTROL is in
effect.
• For Model profiles: To specify a model profile (using, as
required, FROM, FCLASS, FGENERIC, and FVOLUME), the
caller must have sufficient authority over the model
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profile (the from profile). RACF makes the following
checks until one of the conditions is met:
◦ The caller has the SPECIAL attribute.
◦ The from profile is within the scope of a group in which
the caller has the group-SPECIAL attribute.
◦ The caller the owner of the from profile.
◦ If the FCLASS operand is DATASET, the high-level
qualifier of the profile name (or the qualifier supplied
by the RACF naming conventions table) is the caller’s
user ID.
◦ For a discrete profile, the caller is on the access list in
the from profile with ALTER authority.
◦ For a discrete profile, the caller’s current connect
group (or, if list-of-groups checking is active, any
group to which the caller is connected) is in the access
list in the from profile with ALTER authority.
◦ For a discrete profile, the universal access authority
(UACC) is ALTER.
Special parameter authorization:
• For use of the ADDMEM operand: In addition to the
authority needed to issue the RDEFINE command, the
caller needs one of the following authorities to add
members using the RDEFINE command:
◦ See the requirements specified for the use of the
ADDMEM operand for the RALTER command.
RDELETE {SM.3::SM.3-R12-RACFEAL5-20} General:
• SPECIAL, or
• The profile is within the scope of a group in which the
caller has the group-SPECIAL attribute, or
• The caller is the owner of the profile, or
• For a discrete profile: the caller has ALTER authority
(either via the standard access list, or via group access or
via UACC)
• For profiles in the FILE or DIRECTRY class: the second
qualifier of the profile name is the caller’s user ID.
REMOVE {SM.3::SM.3-R12-RACFEAL5-21} General:
• SPECIAL, or
• The profile is within the scope of a group in which the
caller has the group-SPECIAL attribute, or
• The caller is the owner of the group, or
• The caller has JOIN or CONNECT authority in the group.
RESTART None (can be used an operator command only. RACF allows
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restricting the use of specific operator commands to defined
users).
RLIST {SM.3::SM.3-R12-RACFEAL5-22} General:
• SPECIAL, or
• The resource profile is within the scope of a group in
which the caller has the group-SPECIAL attribute, or
• OPERATIONS, or
• The resource profile is within the scope of a group in
which the caller has the group-OPERATIONS attribute, or
• AUDITOR, or
• The resource profile is within the scope of a group in
which the caller has the group-AUDITOR attribute, or
• The caller is the owner of the resource.
• If the profile is in the FILE or DIRECTRY class and the
second qualifier of the profile name is the caller’s user ID.
(Note: the FILE and DIRECTRY classes apply only in z/VM
systems, and will not be considered in this evaluation
even though the classes exist in RACF for z/OS.)
• To list the contents of segments other than the base
segment, the caller must have the SPECIAL or AUDITOR
attribute or the installation must permit the caller to do so
through field-level access checking.
• If the caller is on the access list for the resource and has
at least READ authority. If you specify ALL, RACF lists only
information pertinent to the caller’suser ID.
• If the caller’s current connect group (or, if list-of-groups
checking is active, any group to which the caller is
connected) is in the access list and has at least READ
authority.
• The universal access authority of the resource is at least
READ.
• The caller has at least read access for the profile name
from the GLOBAL ENTRY TABLE (if this table contains an
entry for the profile).
Other:
• The caller will see the type of access attempts, as
specified by the GLOBALAUDIT operand, only if he has the
AUDITOR attribute or if the resource profile is within the
scope of a group in which he has the group-AUDITOR
attribute.
RVARY General: none
{SM.3::SM.3-R12-RACFEAL5-32} Other:
• No special authority is needed to issue the RVARY
command. However, the operator (at the operator console
or security console) must approve a change in RACF
status or the RACF data sets - or a change in the
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Command Authorities required for use
operational mode if RACF is enabled for sysplex
communication - before RACF allows the command to
complete.
• If the RVARY command changes RACF or database status
(ACTIVE/INACTIVE), RACF issues an informational message
and the operator is required to enter the password
defined by RVARYPW STATUS(status-pw) to authorize the
change. If the RVARY command switches the RACF data
sets (SWITCH) or changes the RACF operating mode
(DATASHARE/NODATASHARE), RACF issues an
informational message and the operator is required to
enter the password defined by RVARYPW SWITCH(switch-
pw). When RVARY is issued as a RACF operator command
from a console with master authority, the default
password YES is also accepted for RVARY ACTIVE, RVARY
NODATASHARE or RVARY SWITCH commands.
SEARCH {SM.3::SM.3-R12-RACFEAL5-23} General:
• SPECIAL, or
• AUDITOR, or
• The profile is within the scope of a group in which the
caller has the group-SPECIAL or group-AUDITOR attribute,
or
• If the profile is for a DASD data set, the high-level qualifier
of the data set name (or the qualifier supplied by the
naming convention table) is the caller’s user ID, or
• If the profile is in the FILE or DIRECTRY class, the second
qualifier of the profile name is the caller’s user ID (note:
the FILE and DIRECTRY classes apply only in z/VM
systems, and will not be considered in this evaluation
even though the classes exist in RACF for z/OS.), or
• The caller is on the access list for the profile and has at
least READ authority, or
• The caller’s current connect group (or, if list-of-groups
checking is active, any group to which the caller is
connected) is on the access list and has at least READ
authority, or
• The caller has the OPERATIONS attribute, or the profile is
within the scope of a group in which the caller has the
group-OPERATIONS attribute, and the class is DATASET or
a general resource class that specifies OPER=YES in the
static class descriptor table or OPERATIONS(YES) in the
dynamic class descriptor table, or
• The universal access authority is at least READ (or
GLOBAL when listing discrete profiles).
Special parameter authorization:
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Command Authorities required for use
• In order to use the USER operand, one of the following
must be true:
◦ SPECIAL, or
◦ AUDITOR, or
◦ The caller is the owner of the user profile, or
◦ The parameter entered for the USER operand is the
caller’s user ID
◦ The caller has group-SPECIAL or group-AUDITOR
authority in a group that owns the user profile.
Other:
• If the SECLABEL class is active, the caller’s current
security label must dominate the security label of the
DASD data set or general resource profile.
• No authorization is required to the user or group profiles
that are listed when the UID or GID keyword is specified.
• Inactive SECLABEL profiles and profiles that contain
inactive security labels may not be listed if SETROPTS
SECLBYSYSTEM is active because only users with SPECIAL
or AUDITOR authority are allowed to view inactive security
labels.
SET {SM.3::SM.3-R12-RACFEAL5-26} None (can be used an operator
command only. RACF allows restricting the use of specific
operator commands to defined users).
SETROPTS {SM.3::SM.3-R12-RACFEAL5-24} General:
• SPECIAL, for all operands except:
◦ APPLAUDIT | NOAPPLAUDIT
◦ AUDIT | NOAUDIT
◦ CMDVIOL | NOCMDVIOL
◦ LOGOPTIONS
◦ OPERAUDIT | NOOPERAUDIT
◦ SAUDIT | NOSAUDIT
◦ SECLABELAUDIT | NOSECLABELAUDIT
◦ SECLEVELAUDIT | NOSECLEVELAUDIT
• AUDITOR, for use of the following operands:
◦ APPLAUDIT | NOAPPLAUDIT
◦ AUDIT | NOAUDIT
◦ CMDVIOL | NOCMDVIOL
◦ LOGOPTIONS
◦ OPERAUDIT | NOOPERAUDIT
◦ SAUDIT | NOSAUDIT
◦ SECLABELAUDIT | NOSECLABELAUDIT
◦ SECLEVELAUDIT | NOSECLEVELAUDIT
Special parameter authorization:
• For using the LIST operand: SPECIAL or AUDITOR
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Command Authorities required for use
Other:
In some situations, a caller can use SETROPTS even if he does
not have the SPECIAL or AUDITOR attributes. These situations
are:
• The LIST operand can be used if the caller has the group-
SPECIAL or group-AUDITOR attribute in the current
connect group or (if GRPLIST is active) in any group that
the caller is connected to.
• The REFRESH operand together with GENERIC can be
used if the caller has the group-SPECIAL, AUDITOR, group-
AUDITOR, OPERATIONS, group-OPERATIONS attribute, or
CLAUTH authority for the classes specified.
• The REFRESH operand together with GLOBAL can be used
if the caller has the OPERATIONS attribute or CLAUTH
authority for the classes specified.
• The REFRESH operand together with RACLIST can be used
if the caller has CLAUTH authority to the specified class.
• The REFRESH operand together with WHEN(PROGRAM)
can be used if the caller has CLAUTH authority for the
program class or the OPERATIONS attribute.
SIGNOFF {SM.3::SM.3-R12-RACFEAL5-27} None (can be used an operator
command only. RACF allows restricting the use of specific
operator commands to defined users).
STOP {SM.3::SM.3-R12-RACFEAL5-28} None (can be used an operator
command only. RACF allows restricting the use of specific
operator commands to defined users).
TARGET {SM.3::SM.3-R12-RACFEAL5-29} None (can be used an operator
command only. RACF allows restricting the use of specific
operator commands to defined users).
Management of z/OS UNIX file systems
z/OS UNIX file systems considered in this evaluation include HFS, zFS, and NFS file systems.
A file system is contained in an MVS data set and must be mounted before it can be used.
Mounting of any of these file systems can occur via the auto-mount functions provided by
z/OS UNIX System Services, or via an administrator-issued “mount” command.
To mount a file system an administrator must have either UID(0) or at least READ authority
to UNIXPRIV resource SUPERUSER.FILESYS.MOUNT {SM.3::SM.3-R13-UNIX-1}.
{SM.3::SM.3-R13-UNIX-2} Additionally, a non-administrator may mount an HFS, zFS, or NFS
file system if all of the following are true:
• The user has at least READ authority to UNIXPRIV resource
SUPERUSER.FILESYS.USERMOUNT.
• The mount point directory must be empty.
• The user must have RWX permissions to the mount point, and if the mount point has
the sticky bit set, the user must be the owner of the mount point.
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• If the mount point directory resides in a remote file system (e.g., NFS), and if the
mount point has the sticky bit set, then owner UID of the mount point directory must
match the user's UID.
• The user must have RWX permissions to the root directory in the file system to be
mounted, and if that root directory has the sticky bit set the user must be the owner
of the root directory.
• The mount command must specify NOSETUID and must not specify NOSECURITY.
• For remote file systems (e.g., NFS), if the file system root has the sticky bit set then
the owner UID of the file system root must match the user's UID.
Management of z/OS UNIX file system objects and IPC objects
Access permissions to z/OS UNIX file system objects and IPC objects are managed by
functions in the z/OS UNIX System Services environment {SM.3::SM.3.35}. The standard
functions to set or modify permission bits to file system objects and IPC objects also exist in
the z/OS UNIX environment and allow users with the required permission to perform those
actions {SM.3::SM.3.36}. In addition functions exist that allow the owner of a file system
object to set or modify the access control list entries of this file system object
{SM.3::SM.3.37}.
8.1.5.4 Network configuration and management
z/OS provides some basic configuration data sets for TCP/IP and TCP/IP based protocols.
Those configuration data sets that are also related to security are:
 PROFILE.TCPIP
Provides TCP/IP initialization parameters and specifications for network interfaces and
routing.
 TCPIP.DATA
Provides parameters for TCP/IP based client and server programs.
 Additional Communications Server configuration information (e.g., IPSec and AT-TLS)
exists in policy files accessed via the Communications Server Policy Agent.
 The IKE daemon, NSS server, Defense Manager daemon, and Policy Agent also have
their own configuration files.
 The HTTP server configuration file (default: httpd.conf)
Configuration statements in those data sets define the properties (including security
properties) of the TCP/IP protocol itself as well as the main protocol server.
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Communications Server ipsec Command Interface
The Communications Server provides a command named ipsec that allows authorized users
to query information about IP filters, defensive filters and IPSec security associations. It also
allows authorized users to activate or deactivate IPSec functions, affect which IP filters are
loaded, and create, update and delete defensive filters. The administrator can control
access to this command by granting READ access to the following resources in the
SERVAUTH class:
 EZB.IPSECCMD.sysname.tcpname.DISPLAY allows clients to display information about
IP filters, per-stack defensive filters and IPSec security associations {SM.4::SM-R10-
CS-IPSECCMD-1}.
 EZB.IPSECCMD.sysname.tcpname.CONTROL allows clients to reload or refresh IP
filters, create, update or delete per-stack defensive filters and activate or deactivate
IPSec security associations {SM.4::SM-R10-CS-IPSECCMD-3}.
 EZB.IPSECCMD.sysname.DMD_GLOBAL.DISPLAY allows clients to display information
about global defensive filters {SM.4::SM-R10-CS-IPSECCMD-4}.
 EZB.IPSECCMD.sysname.DMD_GLOBAL.CONTROL allows clients to create, update or
delete global defensive filters {SM.4::SM-R10-CS-IPSECCMD-6}.
Communications Server Network Management Interface
The Communications Server provides, via the IKE daemon, a network management interface
(NMI) that allows local applications to query information about IP filters and IPSec security
associations. It also allows applications to activate or deactivate IPSec functions. The IKE
daemon provides this information via a UNIX (not TCP/IP) socket. The administrator can
control access to this interface by granting READ access to the following resources in the
SERVAUTH class:
 EZB.NETMGMT.sysname.tcpname.IPSEC.DISPLAY allows clients to display information
about IPSec filtering and security associations. If not defined, applications must run
with UID(0) or access to BPX.SUPERUSER in order to use the interface {SM.4::SM-
R10-CS-SECMON-1}.
 EZB.NETMGMT.sysname.tcpname.IPSEC.CONTROL allows clients to issue
management requests to activate, deactivate, or modify IPSec security associations.
If not defined, applications must run with UID(0) or access to BPX.SUPERUSER in
order to use the interface. {SM.4::SM-R10-CS-SECMON-3}.
 EZB.NETMGMT.sysname.sysname.IKED.DISPLAY allows clients to display information
about IKE daemon usage of the Network Security Services (NSS) client functions via
the NMI or the ipsec command with the -w option. If not defined, applications must
run with UID(0) or access to BPX.SUPERUSER in order to use the interface.
{SM.4::SM-R10-CS-SECMON-4}.
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Additionally, the Network Security Services (NSS) server provides a network management
interface that allows a central administrator to monitor and control NSS and IPSec
information in a manner similar to that provided by the IKE daemon. For these network
management requests, the administrator can use the following SERVAUTH resources to
provide protection:
 EZB.NSS.sysname.clientname.IPSEC.NETMGMT allows clients to register with the NSS
server for IPSec network management services SM.4::SM-R9-CS-NSS-1}.
 EZB.NETMGMT.sysname.clientname.IPSEC.DISPLAY allows clients to display IPSec-
related information via the NSS NMI or the ipsec command with the –z option
{SM.4::SM-R9-CS-NSS-2}.
 EZB.NETMGMT.sysname.clientname.IPSEC.CONTROL allows clients to issue
management requests to activate, deactivate, or modify IPSec security associations
via the NSS NMI or the ipsec command with the –z option {SM.4::SM-R9-CS-NSS-3}.
 EZB.NETMGMT.sysname.sysname.NSS.DISPLAY allows clients to display information
about current NSS client connections to the NSS server via the NSS NMI or the ipsec
command with the –x option {SM.4::SM-R9-CS-NSS-4}.
Communications Server Policy Agent
The Communications Server provides a Policy Agent that can act in any of several roles,
depending on configuration options:
 The Policy Agent may act as the Policy Definition Point (PDP) on a single system,
installing policies in one or more z/OS Communications Server stacks {SM.4::SM-R9-
CS-POLCEN-1}.
 The Policy Agent may act as a centralized policy server, providing PDP services for
one or more remote policy clients {SM.4::SM-R9-CS-POLCEN-2}.
 The Policy Agent may act as a policy client, retrieving remote policies from the policy
server. Each stack in a Common INET (CINET) environment acts as a separate policy
client {SM.4::SM-R9-CS-POLCEN-3}. Communications between the policy client and
the policy server may optionally be secured by AT-TLS {SM.4::SM-R10-CS-POLCEN-
11}.
A single Policy Agent may act as a policy client or a policy server, but not both {SM.4::SM-
R9-CS-POLCEN-11}.
Policies may be defined in several different ways. When acting as the PDP for a single
system, Policy Agent can read policy definitions from local configuration files, a central
repository that uses the Lightweight Directory Access Protocol (LDAP), or both {SM.4::SM-
R9-CS-POLCEN-4}.
The Policy Agent also installs policies in one or more z/OS Communications Server stacks. It
can be used to replace existing policies or update them as necessary {SM.4::SM-R9-CS-
POLCEN-5}.
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When acting as a policy server, Policy Agent also acts as a PDP for the local system, and so
can read policies from local configuration files or an LDAP server, and install them in local
stacks {SM.4::SM-R9-CS-POLCEN-6}. But it also reads policies from local configuration files
on behalf of policy clients. These policies are retrieved by policy clients, but are not installed
in the local stacks on the policy server {SM.4::SM-R9-CS-POLCEN-7}.
When acting as a policy client, Policy Agent retrieves remote policies from the policy server,
and can also use local policies from configuration files or an LDAP server {SM.4::SM-R9-CS-
POLCEN-8}.
The choice of local or remote policies can be made separately for each type of supported
policy: Quality of Service (Qos), Intrusion Detection (IDS), Policy-Based Routing (PBR), IPSec,
or AT-TLS {SM.4::SM-R9-CS-POLCEN-9}. For a given policy type, all policies are obtained
either locally or remotely {SM.4::SM-R9-CS-POLCEN-10}.
When acting as a policy server, the policy agent will:
 First, authenticate its clients using a RACF user ID and password or PassTicket
{SM.4::IA-R9-CS-POLCEN-1}.
 Then, authorize retrieval of policy data, requiring READ access to policy agent
resources in the SERVAUTH class. These resources must be protected or retrieval will
fail {SM.4::AC-R9-CS-POLCEN-1}. They have the form
EZB.PAGENT.sysname.image.ptype {SM.4::AC-R9-CS-POLCEN-2} where
o Sysname is the system name defined in the sysplex
o Image is the TCP name or policy client name
o Ptype is either QOS, IDS, IPSEC, or (for AT-TLS) TTLS.
8.1.5.5 PKI Services
PKI Services allows an installation to establish a Public Key Infrastructure (PKI) and serve as
a certificate authority for its internal and external users, issuing and administering digital
certificates in accordance with the organization's policies. Users can use a PKI Services
application to request and obtain certificates through their own Web browsers {SM.5::SM-
R8-PKI-1}, while authorized PKI administrators approve, modify, or reject these requests
through their own Web browsers, Microsoft Internet Explorer version 5.x or higher
{SM.5::SM-R8-PKI-2} or Netscape Communicator version 4.x or higher {SM.5::SM-R8-PKI-3}.
The Web applications provided with PKI Services are highly customizable. An installation can
allow automatic approval for certificate requests from certain users {SM.5::SM-R8-PKI-4}
and, to provide additional authentication, add host IDs, such as RACF user IDs, to certificates
issued for certain users {SM.5::SM-R8-PKI-5}. Installations can also issue certificates for
browsers, servers, and other purposes, such as virtual private network (VPN) devices, smart
cards, and secure e-mail.
PKI Services CA’s signing key length can be up to 4096 bits for RSA, up to 1024 bit for DSA,
521 bits for NIST ECC, or 512 bits for Brainpool ECC {SM.5::SM-R12-PKI-6}.
PKI Services can generate RSA keys up to 4096 bits for the certificates if requested
{SM.5::SM-R12-PKI-37}.
PKI Services can generate NIST ECC keys with maximum length 521 bits for the certificates if
requested {SM.5::SM-R12-PKI-41}.
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PKI Services can generate Brainpool ECC keys with maximum length 512 bits for the
certificates if requested {SM.5::SM-R12-PKI-42}.
PKI Services may be configured to accept and process certificate requests and revocation
requests through the Certificate Management Protocol (CMP). Certificate requests may
contain the public key of a public/private key pair, or may be omitted to instruct the PKI
Service CMP CGI program to generate the key pair. {SM.5::SM-R12-PKI-43}
Supported Certificate Fields and Extensions
PKI Services certificates support fields and extensions defined in the X.509 version 3
(X.509v3) standard. It can include the following types of extensions:
Standard extensions {SM.5::SM-R8-PKI-7}
The standard X.509v3 certificate extensions:
 authority information access
 authority key identifier
 basic constraints
 certificate policies
 certificate revocation list (CRL) distribution points
o Distinguish Name format
o Uniform Resource Identifier format using LDAP or HTTP protocol
 key usage
o digitalSignature
o nonRepudiation
o keyEncipherment
o dataEncipherment
o keyAgreement
o keyCertSign
o CRLSign
 extended key usage
o serverauth
o clientauth
o codesigning
o emailprotection
o timestamping
o ocspsigning
o mssmartcardlogon
 subject alternate name
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o email
o domain
o IPAddress
o uniformResourcesIdentifier
o OtherName
 subject key identifier
Other extensions
• host identity mapping {SM.5::SM-R8-PKI-8}. This extension associates the subject of
a certificate with a corresponding identity on a host system, such as with a RACF user
ID.
• Custom extensions {SM.5::SM-R12-PKI-44}. This allows users to create any
extensions conformed to the Extension structure: a sequence of OID, critical flag and
value.
Supported Certificate Revocation List Fields and Extensions
PKI Services generates CRLs that comply with the X.509 version 3 (X.509v3) standard. The
following extensions are included:
CRL extensions: {SM.5::SM-R8-PKI-9}
 AuthorityKeyIdentifier
 CRLNumber
 IssuingDistributionPoint
CRL entry extensions: {SM.5::SM-R8-PKI-10}
 CertificateIssuer
 CRLReason
o Unspecified
o keyCompromise
o cACompromise
o affiliationChanged
o superseded
o cessationOfOperation
o certificateHold
 InvalidityDate
Certificate Templates
PKI Services will only generate certificates that are consistent with the currently defined
Certificate templates. PKI Services shipped with sample certificate templates of the most
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commonly requested certificate types. You can add, modify, and remove certificate
templates to customize the variety of certificate types you offer to your users.
PKI Services templates support generating certificates for the following uses or with the
following characteristics:
 SSL Client authentication {SM.5::SM-R8-PKI-11}.
o key usage: digitalSignature and keyEncipherment
o extended key usage: clientauth
 SSL Server authentication using SSL {SM.5::SM-R8-PKI-12}.
o Key usage: digitalSignature and keyEncipherment
o Extended key usage: serverauth
 IPSEC Firewall server {SM.5::SM-R8-PKI-13}.
o Key usage: digitalSignature, keyEncipherment and dataEncipherment
 Certificate Authority {SM.5::SM-R8-PKI-14}.
o Key usage: keyCertSign and CRLSign
 z/OS authentication {SM.5::SM-R8-PKI-15}.
o Key usage: digitalSignature and keyEncipherment
o Extended key usage: clientauth
o Host Identity Mapping
 S/MIME email protection {SM.5::SM-R8-PKI-16}.
o Key usage: digitalSignature and keyEncipherment
o Subject alternate name: email
 Code signing {SM.5::SM-R8-PKI-17}.
o Key usage: digitalSignature and docSign
o Extended key usage: codeSigning
o Subject alternate name: email
o Authority Information Access: basic
 Windows logon {SM.5::SM-R8-PKI-18}.
o Key usage: digitalSignature
o Extended key usage: clientauth, mssmartcardlogon
 Network device using the Simple Certificate Enrollment Protocol (SCEP) {SM.5::SM-
R8-PKI-19}.
 Certificate with key pair generated by PKI Services {SM.5::SM-R11-PKI-38}.
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Distribution of certificates
Other than sending the certificate back to the requestor through the browser, PKI Services
can also post the issued certificates to LDAP according to the LDAP standard for
communications with the Directory {SM.5::SM-R8-PKI-20}.
If the key pair for the certificate was generated by PKI Services, an email with a link
embedded with the transaction ID will be sent to the requestor for him to pick up the
certificate packaged with the private key {SM.5::SM-R11-PKI-39}.
Providing Certificate status
PKI Services provides certificate status information through Certificate Revocation Lists
(CRLs) whose format complies with the X.509 standard and, the Online Certificate Status
Protocol (OCSP) standard as defined by RFC 2560 for a “basic” OCSP responder {SM.5::SM-
R8-PKI-21}.
The CRLs can be posted to LDAP according to the LDAP standard for communications with
the Directory {SM.5::SM-R8-PKI-22}, or posted to an HFS file {SM.5::SM-R8-PKI-23}.
End User Functions
The end user can use the end user web pages to perform the following tasks:
 Install a CA certificate into the browser {SM.5::SM-R8-PKI-24}
 Request a new certificate {SM.5::SM-R8-PKI-25}
 Pick up a previously requested certificate {SM.5::SM-R8-PKI-26}
 Renew or revoke a previously issued browser certificate {SM.5::SM-R8-PKI-27}
 Recover a previously requested certificate and its private key , which requires
specification of the email address and passphrase of the original request{SM.5::SM-
R11-PKI-40}
Administrator Functions
The administrator can use the administration web pages to perform the following tasks:
 Process a certificate request
o Approve a request without making changes {SM.5::SM-R8-PKI-28}
o Approve a request with changes {SM.5::SM-R8-PKI-29}
o Reject a request {SM.5::SM-R8-PKI-30}
o Delete a request {SM.5::SM-R8-PKI-31}
 Process a certificate
o Revoke a certificate {SM.5::SM-R8-PKI-32}
o Suspend a certificate {SM.5::SM-R8-PKI-33}
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o Resume a certificate {SM.5::SM-R8-PKI-34}
o Delete a certificate {SM.5::SM-R8-PKI-35}
 Perform searches for certificate requests and certificates {SM.5::SM-R8-PKI-36}
Security Administration for PKI Services
PKI Services security administration comprises the following tasks:
 Authorizing users for the PKI Services administration group (connecting and deleting
members)
 Authorizing users for inquiry access
8.1.5.6 Security Management for System Logger Log Streams
Applications can read and write to defined log streams as explained in the DAC section of
this document. However, before they can do this an administrator or an application must
define the log stream and the policies that apply to it.
The system policy for log streams exists in an MVS data set known as the “LOGR couple data
set”. Administrators who need to define or view the logger policy information use the
IXCMIAPU utility program to do so. They require:
 READ authority to the MVSADMIN.LOGR resource in the FACILITY class in order to
generate reports about the logger policy {SM.6::SM-R9-LOGGER-1}.
Additionally, logger administrators who need to define, in the CFRM policy, coupling facility
structures that will be utilized by log streams will also need UPDATE authority to the
MVSADMIN.XCF.CFRM resource in the FACILITY class {SM.6::SM-R9-LOGGER-3}.
Additionally, logger administrators who need to define, delete, or modify the definitions of
log streams will need:
 ALTER authority to resource log_stream_name in class LOGSTRM to define, delete, or
update the stream {SM.6::SM-R9-LOGGER-4}
 ALTER authority to resource MVSADMIN.LOGR in class FACILITY to define or delete a
coupling facility structure for use by a log stream {SM.6::SM-R9-LOGGER-6}.
 UPDATE authority to resource IXLSTR.structure_name in class FACILITY to associate
the named coupling facility structure with a log stream {SM.6::SM-R9-LOGGER-7}.
Applications wishing to administer log streams using the programming interfaces will need:
 ALTER authority to resource log_stream_name in class LOGSTRM to define, update
the definition of, or delete a log stream {SM.6::SM-R9-LOGGER-8}.
 Additionally, UPDATE to resource name IXLSTR.structure_name in class FACILITY to
define a log stream that uses a coupling facility structure {SM.6::SM-R9-LOGGER-9}
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 Additionally, when defining a log stream modeled upon the definition of another log
stream, UPDATE access to resource IXLSTR.model_structure_name in class FACILITY
(when the model stream has a structure) {SM.6::SM-R9-LOGGER-10}.
 ALTER to resource MVSADMIN.LOGR in class FACILITY if they wish to use logger
interfaces to define coupling facility structures {SM.6::SM-R9-LOGGER-11}
8.1.6 Auditing
8.1.6.1 Generation of audit records
The TOE provides a general facility to collect data required for auditing and accounting
services. This function, the System Management Facilities (SMF), collects and records
system and job-related information that an installation can use for such tasks as the
following:
 Billing users
 Reporting reliability
 Analyzing the configuration
 Scheduling jobs
 Summarizing direct access volume activity
 Evaluating data set activity
 Profiling system resource use
 Maintaining system security
This component is used by the TOE to collect security-related auditing information as
required by FAU_GEN.1 and FAU_GEN.2.
Each SMF record consists of a standard header which contains (among other information)
the type of the record and the time the record was produced {AU.1::AU.1.1}. SMF supports
up to 256 different record types. SMF records can only be generated by authorized
processes or processes specifically authorized to generate specific types of SMF records
under the mediation of the TOE {AU.1::AU.1.2}.
One record type is usually reserved for a whole class of events where the individual events
are identified by the record subtype or event code in the header of the SMF record.
RACF as the central access control function has three SMF record types reserved for its use
(80, 81, 83), with record type number 80 being the most important one. The information
recorded in this record type contains (among other non security related information):
 The record type
 Time stamp (time and date)
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 System identification
 Event code and qualifier
 User identification
 Group name
 Authorities used to successfully execute commands or access resources
 Reasons for logging
 Command processing error flag
 Foreground user terminal ID or other port-of-entry information
 Job log number (job name, entry time, and date)
 RACF version, release, and modification number
 SECLABEL of user (relevant in Labeled Security Mode only)
Each record contains further data specific to the event code and qualifier {AU.1::AU.1.3}.
The administrator can configure RACF and other elements of the TOE to generate audit
records for all events listed in Table 7: Auditable Events {AU.1::AU.1-R9-MULTI-1}.
z/OS provides the capability to search the audit trail for specific events and relate them such
that events related to a specific user, specific user/job sensitivity label (Labeled Security
Mode) or specific object sensitivity label ( Labeled Security Mode) can be extracted from the
audit trail {AU.1::AU.1.4}.
Tools exist that allow user with access to the audit trail data to search the audit trail for
specific events, for audit events related to specific jobs / users and other criteria
{AU.1::AU.1.5}. Tools exist that transfer the audit data into human readable format
{AU.1::AU.1.6}.
RACF also allows LDAP clients (typically servers outside of the TOE, residing on the network)
that have authenticated using an ICTX-style DN to request RACF to generate audit records to
record events that have occurred externally to the TOE. The requester provides information
about the user involved with the event, the kind of event, and the resource name and
resource class name (any class except DATASET) associated with the event.
The LDAP client uses an LDAP extended-operation to request this auditing function. Usage of
the remote auditing service requires the LDAP client to have READ authority to FACILITY
resource IRR.LDAP.REMOTE.AUDIT {AU.1::AC.2-R9-EIM.5}. The audit record will be created
as an SMF type 83 subtype 4 record {AU.1::AU.1-R9-EIM-1}.
If an application has created an ACEE and specified ICTX= on the RACROUTE
REQUEST=VERIFY to associate a X.500-format distributed identity with the RACF user's
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ACEE, RACF will include that distributed identity in the SMF records that it creates.
{AU.1::AU.1-R12-RACF-1}
8.1.6.2 Protection of the audit trail
SMF writes audit records into either
xvii. Dedicated SMF data sets that have been defined during system configuration. At
least two SMF data sets must be defined by the administrator for compliance with the
evaluated configuration. Those data sets need to be protected against unauthorized
access by appropriate RACF access control lists. The administrator guidance
documentation provides specific guidelines for the protection of the audit trail using
RACF.
Or
xviii. A system log stream, which may reside solely in DASD data sets, or in a
combination of data sets and a coupling facility structure for better performance, as
specified by the administrator. The administrator configures profiles in the LOGSTRM
class to control who can access the data while it exists in the managed log stream,
and profiles in the DATASET class to control access to any data extracted from the
log stream.
8.1.6.3 Using MVS Data Sets for SMF
When the system is started SMF searches for the first non-full data set in the list of SMF data
sets defined. This data set becomes the active SMF data set used to store audit records.
Once this data set is full, SMF marks the data set to be processed by the SMF Dump program
and takes the next empty data set as the active, searching the list of SMF data sets in a
wraparound way {AU.2::AU.2.2}. The operator is also alerted to switch the data set.
SMF data sets that are full need to be processed by the SMF Dump program, IFASMFDP. This
program copies the content of a full SMF data set to another data set (the “dump data set”)
defined by the installation and marks the SMF data set as empty {AU.2::AU.2.3}. The SMF
Dump program itself creates two SMF records (Dump Header and Dump Trailer) that are
stored in the beginning and at the end of the dump data set {AU.2::AU.2.4}. Dump data sets
must be protected by RACF access control lists.
If no non-full data set is found, SMF stores the records in its buffers until a data set is made
available {AU.2::AU.2.5}. If the TOE is configured according to the administrative guidance,
the system will halt if no buffer space is left {AU.2::AU.2.6}.
8.1.6.4 Using a System Log Stream for SMF
In contrast to using MVS data sets directly, when using a log stream for the SMF data only
one logical stream exists. Although this stream may reside in multiple MVS data sets as
determined by system logger processing, the administrator will view the stream as one
logical entity, starting with the earliest available data and ending with the current data,
rather than dealing with the individual data sets.
Operators do not need to switch SMF data sets, nor dump them to archive storage, nor clear
them. Rather, the data can simply reside in the logger-managed data sets.
z/OS provides the IFASMFDL utility program that can extract an administrator-specified set
of SMF data from the log stream, based on time/date, system ID, and/or SMF record type
and write that extracted data to a standard MVS data set for later processing {AU.2::AU-R9-
SMF-1}.
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IFASMFDL can invoke exit routines, just as IFASMFDP can, and so the RACF SMF Unload
routine will work with IFASMFDL just as with IFASMFDP, providing an interpreted flat-file of
RACF-relevant security records for subsequent analysis {AU.2::AU-R9-RACF-1}.
8.1.6.5 Audit configuration and management
Within the system configuration it needs to be decided, which SMF records shall be
generated by z/OS. Three record types (type 80, 81, and 83) are dedicated to RACF and are
the most important ones for security. Which events are actually recorded with those records
can be configured by a user with the AUDITOR attribute in his RACF user profile
{AU.3::AU.3.1}. In addition record type 30 is generated for a number of security related
events.
Because a set of mandatory events is always audited, not all audit records (such as
unauthorized attempts to access the system or changes to the status of the RACF database)
can be configured.
In addition, resource profiles can define which events related to this resource are audited
{AU.3::AU.3.2}. The owner of a resource profile as well as a user in the AUDITOR role are
able to change the entries related to auditing within the resource profile {AU.3::AU.3.3}.
The system can be configured to send certain audit messages to the security console to
immediately alert operators of detected policy violations {AU.3::AU.3.4}.
8.1.7 Object reuse
z/OS provides explicit object reuse functionality for the following objects, and z/OS ensures
that these objects are prepared for reuse before they are allocated to another subject:
 Memory objects are filled with zeros before they are allocated for the first time to a
subject {OR.1::OR.1.1}.
 z/OS data sets are erased when the data is released when the erase-on-scratch
option is active {OR.1::OR.1.2}.
 z/OS system log streams that reside in z/OS data sets are cleared by the system
logger before it writes any data into them. Similarly, for z/OS log stream data residing
in a coupling facility the system logger clears the structure data in the coupling
facility before writing any data into the structure {OR.1::OR.1-R9-LOGGER-1}.
 z/OS tape volumes are erased when they are returned to the scratch pool by
appropriately configuring the SECCLS parmlib option for the parmlib member
EDGRMMxx {OR.1::OR.1-R8-RMM-1} or under control of the appropriate data set
profile’s ERASE option when TAPEAUTHDSN=YES is specified in
SYS1.PARMLIB(DEVSUPxx) {OR.1::OR.1-R8-RMM-2}.
 z/OS UNIX file system objects and z/OS UNIX IPC objects are cleared before they are
made accessible to a new subject {OR.1::OR.1.3-R13}.
 LDAP LDBM objects are not specifically cleared when they are deleted, but LDAP does
ensure that any data returned from an object is not residual data from some previous
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object that may have occupied the same physical space in the LDBM database
{OR.1::OR.1-R8-LDAP-1}.
8.1.8 TOE self-protection
8.1.8.1 Supporting mechanisms of the abstract machine
The following section provides a short overview of the supporting protection mechanisms of
the abstract machine on which z/OS is running. The purpose of this section is to better
understand how z/OS uses those mechanisms to protect itself against tampering and
bypassing of the security functions of z/OS.
Processor features
The System z processors have two distinctive states: problem and supervisor. A bit in a
processor internal special register, the program status word (PSW) indicates if the processor
is in problem or supervisor state. When in problem state the processor will not execute so
called “privileged instructions”. Those include instructions to perform I/O operations, modify
the content of processor control registers, set storage keys for pages within real memory,
modify the hardware support tables for virtual memory management or modify critical parts
of the PSW like the problem/supervisor bit or the storage key mask bits. When a program in
problem state tries to execute one of those instructions, the processor generates a program
check interrupt {SP.1::SP.1.1}.
Pages within real storage can be protected using a so-called “storage key” that can be
associated with each page of real storage. Programs can modify data within a page only if
the storage key in the current PSW matches the storage key of the page or if the storage
key in the current PSW is zero {SP.1::SP.1.2}. In addition pages can have an indicator,
stating if the page is fetch protected. If this is the case, a program can read data from the
page only if the storage key of the page and the storage of the program in the PSW match or
if the storage key in the PSW is zero {SP.1::SP.1.3}. Storage protection is in effect whether
the processor is in problem or supervisor state. There is one exemption from the rules stated
above: If the “Storage Protection Override Control” bit is set in control register 0 of the
processor, programs executing with storage key 8 are allowed to store and fetch into
storage and from storage with a key of 9.
All processors within a machine share the real storage except for the first 8 KB, which are
individual for each processor. The first 8 KB contain the PSWs loaded upon an interrupt.
When a program issues a supervisor call instruction the processor stores the current PSW of
the calling program (which contains the instruction pointer pointing to the instruction
following the supervisor call instruction) into a fixed location in the processor individual real
storage in the first 8KB and loads a dedicated PSW from another location within the first
8 KB. The same procedure applies for interrupts, where each type of interrupt has dedicated
locations for the “old” PSW to store and the “new” PSW to fetch. All those locations are
within the first 8 KB. Program Call instructions save the current PSW (plus some other
information on the caller’s context) in the linkage-stack program-call state entry. Control
Register 15 serves as a stack pointer to the linkage-stack.
The processor also contains support for virtual memory management. This support allows
z/OS to define separate virtual address spaces and define the protection within those
address spaces on a per page basis.
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In addition to the main processor there is a dedicated I/O hardware subsystem, the
“Channel” subsystem that allows I/O operations to be performed in parallel to the normal
processor operation. Configuring and programming the I/O subsystem is restricted to
programs operating in supervisor state.
The hardware also provides a single time reference within a machine that can be used by all
processors. Different time references within different processors in a parallel sysplex may
also be synchronized by the hardware. Only users with the privileges to use the operator
command to set and change the time may modify the time and date in the TOE
{SP.1::SP.1.4}.
Abstract machine modes of operation
z/OS may execute in one of these modes:
 logical partition mode
 VM guest mode
In all of those cases, z/OS operates on an abstract machine that implements the
z/Architecture.
In logical partition mode, z/OS has full control of all of the resources allocated to the
partition when it has been set up on the hardware management console. The logical
partitioning software (PR/SM) starts the processors allocated to a partition in the
“interpretative execution” mode using the SIE instruction. Each processor is then “confined”
into the boundaries specified for the logical partition with respect to the physical memory
and the channels it can access. Whenever a resource “virtualized” by PR/SM is accessed by
an instruction on a processor, the processor breaks out of the interpretative environment
into the PR/SM code which then services the request in accordance with its own policy. For
z/OS this operation is transparent. PR/SM is part of the TOE environment that provides the
abstract machine for the operation. PR/SM has been evaluated separately.
In VM guest mode, z/OS is operating within the boundaries defined by the z/VM operating
system. z/VM is similar to PR/SM but provides more virtualization functions and more
services a guest operating system may request from the virtual machine monitor. Like
PR/SM z/VM also uses the SIE instruction to run a guest operating system within the
boundaries of the virtual machine. z/VM itself may operate within a logical partition. When
z/OS is operating in VM guest mode, the virtual machine monitor system z/VM is part of the
TOE environment. z/VM itself is subject to a separate evaluation.
8.1.8.2 Supervisor state routines in z/OS
System services offered by z/OS can be invoked from programs running in problem state
using the supervisor call (SVC) and Program Call (PC) instructions of the processor. When the
SVC instruction is executed, the executing processor generates an interrupt, stores the
current PSW at a fixed location in absolute memory, loads a new PSW from another fixed
location in absolute storage and proceeds execution at the address and with the privilege
settings defined in this new PSW. During system startup z/OS has defined the new PSW to be
loaded into the absolute storage in case of an interrupt or exception for all interrupts and
exceptions that may occur. The new PSW contains the address of the SVC interrupt handler
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and z/OS checks if the caller has the required privileges to obtain the requested service
before providing it.
When a Program Call instruction is executed, the hardware checks the authorization of the
caller to call the requested PC routine. A program-call number specified by the second
operand address is used in a multi-level lookup to locate an entry-table entry (ETE). The
program is authorized to use the ETE when the AND of the PSW-key mask in control register
3 and the authorization key mask in the ETE is nonzero or when the CPU is in the supervisor
state. The ETE also defines the entry point address of the PC routine and if the PC routine
will run in supervisor or problem state.
A number of SVC and PC system services as well as specific parameters of system services
are restricted to authorized programs and the service will be rejected if the caller is not
authorized. The concept of authorization is discussed in more detail in the next two sections.
8.1.8.3 Authorized programs
In addition to supervisor and PC routines, z/OS has a number of “authorized programs” that
need to be trusted because they are not restricted by the security policy defined in this
Security Target. An authorized program may call a number of program calls or supervisor
calls or use supervisor call parameters that are reserved for authorized programs. In
particular, it is authorized to call the MODESET SVC used to switch into supervisor state.
With this function, authorized programs can execute any privileged instruction.
A program is authorized if at least one of the following conditions is true:
 The program is executing in supervisor state {SP.3::SP.3.1}
 The program is executing with a PSW key of 0 to 7 or a PSW key mask value that
supports at least one key in the range of 0 to 7 in control register 3 {SP.3::SP.3.2}.
 The authorization bit is set in the Job Step Control Block (JSCB) under which the
program is executing {SP.3::SP.3.3}.
Whenever a supervisor routine reserved for authorized programs is called or when a
parameter reserved for authorized programs is used, the routine invoked to service the
request checks if one of the above listed conditions is satisfied. Only if this is true, the
request is honored {SP.3::SP.3.4}. Note that the hardware performs some checks when a
supervisor routine is called with a Program Call (PC) instruction. In this case the routine
implementing the service only needs to perform its own checks if additional restrictions to
those implied by the hardware checks apply. Note also that some supervisor routine may be
more restrictive, i. e. only a subset of the three conditions mentioned above is checked and
the request is rejected if not one of the conditions in the subset apply. For example the
hardware can not check if a program running in problem state with a PSW key of 8 is
authorized by the authorization bit in the JSCB.
An authorized program can be started in one of the following ways:
 By starting a program from a dedicated program library (defined in the system
configuration data set SYS1.PARMLIB) that has the authorization bit set in the
directory entry of the member of the partitioned data set (library) containing the
program. This program has to be the one started with the EXEC JCL statement of the
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job step, as a TSO command, as a UNIX process using exec(), or started as a
dedicated task by an authorized program using the ATTACH supervisor call with
parameters reserved for authorized programs {SP.3::SP.3.5}
Note: TSO commands might be entered directly by the user at a terminal, executed
in a batch job that runs TSO TMP, or entered programmatically using the TSO
IKJEFTSR service. They may also be executed by any service that uses either the TMP
or IKJEFTSR service such as the REXX 'address tso' function or the Unix shell 'tsocmd'
function.
 By starting a started task from an authorized library using the operator START
command {SP.3::SP.3.6}
 By starting an authorized program from a zFS file system {SP.3::SP.3.V1R7.1}. A
program in a zFS file system is authorized when the authorization bit has been set
using the extattr –a command for the file containing the program
{SP.3::SP.3.V1R7.2}. A user needs to have been authorized to the BPX.FILEATTR.APF
profile in the FACILITY class to set the authorization bit {SP.3::SP.3.V1R7.3}. If a
program running in an APF-authorized address space attempts to load a program
from zFS that does not have the APF-extended attribute set, the load is rejected
{SP.3::SP.3.V1R7.4}. Sanction lists can be defined that restrict access of authorized
programs in the z/OS Unix System Services environment to files and directories
defined in those sanction lists {SP.3::SP.3.V1R7.5}.
Libraries that can contain authorized programs need to be protected from unauthorized
modifications including the possibility to add new programs to the library. zFS files
containing authorized programs also need to be protected from unauthorized modifications.
The discretionary and mandatory access control features of z/OS have to be used to protect
those libraries.
The IKJTSOxx member of SYS1.PARMLIB can be used to define the authorized programs and
commands that can be executed in the TSO environment {SP.3::SP.3.V1R7.6}.
Some trusted subsystems of z/OS are started as part of the standard startup procedure or
may be later started by explicit request of a properly authorized user.
Protection of authorized programs
Authorized programs need to be trusted because they are allowed to increase their
privileges up to running in supervisor mode with a storage key of zero. Authorized programs
therefore must be carefully protected from unauthorized modification and the system must
be protected from adding authorized programs other than those allowed in the evaluated
configuration.
A program executes with authorization when:
 the program was linked with an authorization code into an authorized library or
assigned the authorization attribute in the zFS file system and
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 the program is the first program started within a job step or is started as an
authorized TSO command. All programs started within the same job step by this
program also run authorized {SP.3::SP.3.7}.
To protect the integrity of the TOE the following security measures must be in place:
 all program libraries that are authorized libraries must be protected from update or
alter access by other than the system administrators using the discretionary and
mandatory access control functions and
 the system configuration library needs to be protected from any modification by
other than the system administrators using the discretionary and mandatory access
control functions
No program other than the programs allowed in the evaluated configuration should be linked
with an authorization code in the authorized libraries or specified in the PPT as having a
system key or supervisor state
Note that once a job step is authorized all programs called as part of the execution of the job
step run with authorization and need to be trusted. The TOE protects trusted programs from
accidentally executing any program from an untrusted library {SP.3::SP.3.8}. Trusted
programs can take deliberate actions to bypass this protection.
Note that when within a non-authorized (untrusted) job step a program linked with
authorization code into an authorized library is called, the program executes without
authorization and will fail if it attempts to use privileges allowed only for programs executing
with authorization {SP.3::SP.3.9}.
8.1.8.4 Program Signing and Verification
The TOE supports digital signatures for program objects stored in PDSE data sets. The
digital signature for a program object is optionally created during the process of "binding"
the object modules into the form of an executable program object and storing it into the
PDSE data set. Later, when a user attempts to load or execute that program the system can
optionally validate the signature and use the result of the validation to determine whether to
allow use of the program or not.
Program Signing
{SP.4::SP.4-R12-Binder-1} Users executing the Binder to create a program object in a PDSE
may optionally specify the SIGN=YES option to request that the Binder attempt to digitally
sign the program object and save the signature in the PDSE directory when it saves the
program object.
{SP.4::SP.4-R12-RACF-1} The Security Administrator authorizes users to perform program
signing by
(a) creating FACILITY class profiles of the form IRR.PROGRAM.SIGNING.groupname.userid or
IRR.PROGRAM.SIGNING.userid or IRR.PROGRAM.SIGNING.groupname or
IRR.PROGRAM.SIGNING (listed here in priority order, and where groupname is the user's
current connect group) and
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(b) providing APPLDATA information in that profile that specifies a hashing algorithm to use
and the key ring (both owning userid and key-ring-name) that contains the code signing
digital certificate to use, and
(c) authorizing the user to access that key ring.
{SP.4::SP.4-R12-RACF-2} The specified key ring must contain a digital certificate to use for
signing, together with the RSA private key for that certificate, and the CA certificate(s) for
the certificate. Certificate requirements:
• The code signing certificate and each CA certificate in the CA chain must be signed
using either the sha256WithRSAEncryption or sha1WithRSAEncryption signature
algorithms.
• The code signing certificate must have code-signing capability in one of the following
ways:
• Either the certificate has no KeyUsage extension, or
• the certificate has a KeyUsage extension with at least the digitalSignature and
nonRepudiation indicators enabled.
• Each CA certificate in the chain must have certificate-signing capability in both of the
following ways:
• Either the certificate has no BasicConstraints extension, or
the certificate has a BasicConstraints extension with the cA indicator enabled.
• Either the certificate has no KeyUsage extension, or
the certificate has a KeyUsage extension with at least the keyCertSign
indicator enabled.
Program Signature Verification
{SP.4::SP.4-R12-RACF-3} The Security Administrator enables program signature verification
by:
• Defining the FACILITY class profile IRR.PROGRAM.SIGNATURE.VERIFICATION and
specifying in the APPLDATA the owning user ID and key-ring name of the key ring
that holds the CA certificates associated with the various code signing certificates,
including the IBM-supplied certificate with the label 'STG Code Signing CA', and
• Defining a PROGRAM profile for IRRPVERS, e.g.,
RDEFINE PROGRAM IRRPVERS ADDMEM('SYS1.SIEALNKE'//NOPADCHK) UACC(READ)
SIGVER(SIGREQUIRED(YES) FAILLOAD(ANYBAD) SIGAUDIT(ANYBAD))
• Defining PROGRAM profiles to protect each signed program that the administrator
wants verified during use, and specifying in that profile's SIGVER segment various
options that tell RACF how to process the verification for the protected programs:
• SIGREQUIRED (YES | NO):
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• YES indicates that the program must have a digital signature;
• NO indicates that it might have one, but is not required to have one.
• FAILLOAD( ANYBAD | BADSIGONLY | NEVER ):
• ANYBAD indicates that if any failures occur during program signature
verification (including administrative setup errors such as missing or
incorrectly defined keyrings, signatures by untrusted signers, or
incorrect or missing signatures) the system should disallow use of the
program.
• BADSIGONLY indicates that if the signature itself is incorrect or missing
the system should disallow use of the program.
• NEVER (the default) indicates that a problem with signature verification
should not prevent use of the program.
• SIGAUDIT (ALL | SUCCESS | ANYBAD | BADSIGONLY | NONE):
• ALL indicates that RACF should audit the result of all signature
verification operations using an SMF type 80 audit record.
• SUCCESS indicates that RACF should audit any successful signature
verification operations.
• ANYBAD indicates that RACF should audit any failing signature
verification operation.
• BADSIGONLY indicates that RACF should audit signature verification
operations that fail due to an incorrect or missing signature.
• NONE indicates that RACF should not audit any program verification
operations.
• Refreshing the PROGRAM profiles using SETR WHEN(PROGRAM) REFRESH, and
running program IRRVERLD. (Note: Running IRRVERLD is required only when the
administrator has made signature verification setup changes since the last IPL.)
8.1.9 Session Locking
The hardware available for the TOE (see section HW-CONFIG) does not provide means for
direct connections of synchronous terminals any more. Since the requirements stated in the
SFRs FTA_SSL.1 and FTA_SSL.2 are targetted towards such direct connections, they are
irrelevant to this TOE and therefore trivially met.
8.1.10 Implementation of cryptographic functions
Several components of the TOE use cryptographic functions as part of their security
functions. With the inclusion of the Integrated Cryptographic Services Facility (ICSF) the
cryptographic functions may be provided by hardware coprocessors attached to the TOE.
ICSF checks for the availability of hardware support for individual cryptographic functions
and uses this when appropriate. In the case where no cryptographic coprocessor is attached
to the TOE, the components that use ICSF for cryptographic operations (IPSec, System SSL,
z/OS Network Authentication Service) will use software implementation of the cryptographic
algorithms. IPSec always requires ICSF for AES support, whether using the hardware or
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software. SSH will always use its own software implementation of the cryptographic
algorithms and will use hardware support only for the key generation process. For the
RACDCERT command, the command issuer chooses, by the keywords chosen, whether to
use ICSF or a software implementation.
Note that CPACF is not considered a cryptographic coprocessor but a native capability of the
z/Architecture processor. While the functions provided by CPACF may differ by different
processor models, the functions provided by the CPACF instructions may be used by any
application.
8.1.10.1 Cryptographic Functions for Application Use
The TOE also provides various cryptographic functions via ICSF that are available for use by
applications running on the system.
{CR.2::CR-R13-ICSF-1} The CSFPSKE and CSFPSKD services provided by ICSF provide the
ability for an application to perform encryption and decryption operations with the following
algorithms and key sizes:
 TDES with CBC block chaining mode and 168-bit key size;
 AES with CBC or GCM block chaining modes and 128- or 256-bit keys.
{CR.2::CR-R13-ICSF-2} The CSFPPKV and CSFPPKS services provided by ICSF provide the
ability for an application to perform encryption and decryption operations with the following
algorithms and key sizes:
 RSA with key sizes up to 4096 as defined by PKCS #1 v1.5
{CR.2::CR-R13-ICSF-3} The CSFPOWH service provided by ICSF provides the ability for an
application to perform message digest generation in accordance with the following
cryptographic algorithms:
 SHA-1
 SHA-256
 SHA-512
{CR.2::CR-R13-ICSF-4} The CSFPOWH service provided by ICSF provides the ability for an
application to generate and verify signatures using the following algorithms and key sizes:
 DSA with:
 L=1024, N=160 bits,

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 RSA with 2048-bit keys using PKCS#1 V1.5
 ECDSA with:
 NIST curve=192
 NIST curve=224
 NIST curve=256
 NIST curve=384
 NIST curve=521
as defined in FIPS 186-3 , Digital Signature Standard (DSS), and specified in ANSI X9.62-
1998, Public Key Cryptography for the Financial Services Industry: The Elliptic Curve Digital
Signature Algorithm (ECDSA).
The hash function can be selected to be either SHA-1, SHA-256, or SHA-512. Note: other
hash functions are supported but no claims about those are made in this Security Target.
Note that on z/OS executing on a z114 or z196 processor that also have a CryptoExpress3
coprocessor installed in coprocessor mode, the CryptoExpress3 provides the implementation
of ECDSA.
8.1.10.2 FIPS 140-2
In addition to providing cryptographic support, several components of z/OS have been
designed to meet the Federal Implementation Processing Standard (FIPS) 140-2 Level 1
criteria. FIPS is a standard that has been issued by the National Institute of Standards and
Technology and Communications Security Establishment (CSE) of the Government of
Canada . This standard specifies security requirements for a cryptographic module which is
utilized within a security system to protect sensitive or valuable information. To meet this
standard, cryptographic modules are tested against requirements defined in the FIPS PUB
140-2, Security Requirements for Cryptographic Modules. These security requirements cover
11 areas related to the design and implementation of a cryptographic module.
The z/OS components designed to meet FIPS 140-2 Level 1 are ICSF and System SSL. When
utilizing these components in FIPS mode, they will restrict cryptographic processing to what
is approved or allowed in FIPS mode.
For System SSL, The algorithms/protocols will be restricted to: symmetric TDES (3-key), AES
CBC (128 and 256 bit); hashing algorithms SHA-1 (160-bit) and SHA-2 (224, 256, 384, 512
bit); asymmetric algorithms RSA (1024-4096 bit) and DSA (1024 bit); Diffie-Hellman key
agreement algorithm DH (2048 bit); TLS V1.0 and TLS V1.1 protocols. {CR.1::CR-R12-SSL-1}
For ICSF, the algorithms will be restricted to: symmetric algorithms TDES (3-key), AES ECB,
CBC, GCM (128, 192 and 256 bit); hashing algorithms SHA-1 (160 bit) and SHA-2 (224, 256,
384 and 512 bit); asymmetric algorithms RSA (1024-4096 bit), DSA (1024bit) and ECDSA
(192-521 bit); Diffie-Hellman key agreement algorithms DH (1024-2048 bit) and EC-DH (160-
521 bit).{CR.1::CR-R12-ICSF-1}
Approved cryptographic algorithms are tested for conformance by inputting defined test
vectors and comparing the output results against expected output vectors. No conformance
testing exists for Diffie-Hellman. {CR.1::CR-R12-SSL-2}{CR.1::CR-R12-ICSF-2}
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Each component has unique methods to control FIPS mode execution.
System SSL applications that execute in FIPS mode must utilize the gsk_fips_state_set API
prior to other System SSL functions {CR.1::CR-R12-SSL-3}. System SSL allows switching
from FIPS to non-FIPS mode but not vice versa {CR.1::CR-R12-SSL-4}.
ICSF applications has 2 methods: 1) Utilizing the FIPSMODE start up option for the ICSF
started task. FIPSMODE allows ICSF to be started in strict FIPS mode, compatibility mode
which allows select applications to execute in FIPS mode or non-FIPS mode {CR.1::CR-R12-
ICSF-3}. Compatibility mode applications by default execute in FIPS mode {CR.1::CR-R12-
ICSF-4}. FIPSEXEMPT.<token-label> in the cryptoz class allows a user (application) to be
exempt from FIPS when using a specified PKCS#11 token {CR.1::CR-R12-ICSF-5} or the
calling application has indicated that the specified key must always be used in a FIPS 140-2
compliant fashion {CR.1::CR-R12-ICSF-6}.
ICSF and System SSL modules that execute within FIPS mode have been digitally signed
during the bind process using RSA and SHA-256 signatures. Upon validation of the
signatures, the modules are verified to ensure they have not been tampered with since
being built. Verification is performed during the module load process {CR.1::CR-R12-SSL-5}
{CR.1::CR-R12-ICSF-7}.
In the evaluated configuration, Application Transparent TLS (AT-TLS) {CR.1::CR-R12-CS-1},
Network Security Services daemon (NSSD) {CR.1::CR-R12-CS-2}, IKED {CR.1::CR-R12-CS-3}
and IPSec support in the Communications Server stack {CR.1::CR-R12-CS-4} allow for
execution in either FIPS or non-FIPS mode.
The following hardware support options for cryptographic functions are available:
8.1.10.3 CPACF
This feature is part of the instruction set of the z/Architecture. Instructions are available for
DES encryption and decryption, TDES encryption and decryption and SHA-1 and SHA-2
hashing. In addition a DES based pseudo-random number generator is provided. The
instructions for those operations are part of the general instructions of a z/Architecture
processor and may therefore be used by programs in any processor state. The instructions
are:
 CIPHER MESSAGE (KM)
 CIPHER MESSAGE WITH CHAINING (KMC)
 COMPUTE INTERMEDIATE MESSAGE DIGEST (KIMD)
 COMPUTE LAST MESSAGE DIGEST (KLMD)
The KMC instruction also provides a DES based pseudo random number generator. For
details of those instructions see [ZARCH].
Specific z/Architecture processor models also support 128-bit, 192-bit, or 256-bit AES
encryption/decryption, and SHA-224, SHA-256, SHA-384, or SHA-512 message digests.
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8.1.10.4 CEX3 in CEX3C mode
The CEX3 in CEX3C mode is a PCI based coprocessor card with its own main processor (a
pSeries processor), a cryptographic hardware coprocessor and its own memory. It contains
an operating system (Linux) on top of which application programs implement the functions
of IBM's Common Cryptographic Architecture (CCA). Basically CCA commands are passed by
the TOE to the coprocessor, processed there and the result is passed back to the TOE.
Logical access to the coprocessor functions is controlled by the TSF and unprivileged
programs can access those functions only through the ICSF component of the TSF and only
for services they are allowed to use.
The coprocessor has the ability to generate RSA key pairs and retain the private key in the
coprocessor. When generating such a key pair the coprocessor would only pass back the
public key and a key identifier that can be used to request the coprocessor to use a specific
private key. The private key will never leave the coprocessor in clear. Only export in
encrypted form for backup purposes is possible.
The CEX3C supports up to 4096-bit RSA key operations for clear and secure keys.
8.1.10.5 CEX3 in CEX3A mode
The CEX3 in CEX3A mode is a PCI based cryptographic coprocessor card that contains the
same hardware as in CEX3C mode but which is used only as an accelerator for RSA
encryption and decryption, and which has disabled the general purpose processor, memory
and operating system. RSA encryption and decryption are the only cryptographic functions
the coprocessor can perform. Since the CEX3A provides no own storage, the key has to be
provided by the TOE each time it uses the coprocessor. The coprocessor can accept keys
both in "normal" format as well as in CRT format (as defined in PKCS#1). The operation code
submitted to the card identifies the operation and the key format. Operation code, input
data, output data, data length, key length and the key are passed in a block to the
coprocessor, which then performs its operation and passed the result back in the output
data field. For applications that just need fast RSA encryption and decryption (e. g. a server
that allows a lot of SSL based connections), this provides a significantly faster method for
RSA operations than using the CEX3 in CEX3C mode the overhead associated with the
operations on the CEX3C card. Of course the CEX3A does not provide an option for "secure"
private keys.
8.1.11 Self-test functions
The underlying hardware of the TOE includes a large set of self-test functions for the correct
operation of the functions of the processor, the memory and the attached I/O devices. Errors
detected by those functions result in a machine-check interrupt (for errors in the processor
or the memory) or an error indicator in the information returned by the TEST SUBCHANNEL
instruction in the case of an error within an I/O device. The conditions that are checked
internally by the underlying hardware are listed in chapter 11 of [ZARCH]. Errors detected by
the hardware will result in the error being reported to the TOE in the machine-check
interruption code. The hardware will determine if the problem allows for a safe handling by
the software running on the hardware (the TOE) and pass control to this software by
generating a machine check interrupt. This is the case where either the hardware could
correct the error or where the error is related to a piece of the hardware that still allows a
CPU to safely treat the error.
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Errors from I/O devices are detected and reported by the channel subsystem of the
hardware. Chapter 16 of [ZARCH] describes in the section on the Subchannel-Status Word
the Subchannel-Status Field values that indicate an error detected by the channel
subsystem including device errors or errors detected in the data being transferred (using
error detection and correction codes as part of the data).
In addition IBM field service has specific utilities that allow to locate the hardware error.
Those include a utility that performs a subset the test performed by the System Assurance
Kernel (SAK) tool used within IBM to verify full compliance to the z/Architecture. Neither the
hardware nor the utilities used by the IBM service personnel are part of the TOE but
extensive and continuous abstract machine testing is performed by the TOE environment.
Due to the extensive self-test functions of the underlying hardware the TOE does not provide
self-test functions of the underlying hardware. Those functions would not be able to identify
and report a problem the self-test functions of the hardware had not already identified and
handled.
8.2 TOE Assurance Measures
The assurance measures provided by the developer to meet the security assurance
requirements for the TOE are based on the developer action elements and the requirements
on content and presentation of evidence elements defined for the individual assurance
requirements in CC Part 3:
SAR Assurance Measures
ADV_ARC.1 The architecture is described in [ARCH], which describes the protection
functionality provided by the underlying hardware and firmware, and in [ABC-
V10], which describes how z/OS uses the supporting hardware functionality to
define separate address spaces and to provide a separated execution
environment for the TSF. In addition the start-up process is described.
ADV_FSP.4 The functional specification for z/OS consists of the description of the
supervisor calls (as the description of the macros used to generate the code
for calling the system function), the description of the commands provided to
users, system administrators and auditors to use and manage the security
functions and the description of the system configuration data sets. In
addition there is a document providing an overview of the system functions
with separate parts for functions available to all programs and functions or
parameters of functions available to authorized programs only.
ADV_IMP.1 IBM provides access to the source code for the evaluation team in the IBM
environment. The implementation representation includes all modules that
comprise the TSF.
ADV_TDS.3 A high-level design of the security functions of z/OS is provided which
describes the TOE design at the subsystem level. This document provides an
overview of the implementation of the security functions within the
subsystems of z/OS and points to other existing documents for further details
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where appropriate.
In addition IBM provides dedicated low-level design documentation for the
modules of all SFR enforcing subsystems of the TOE and summary
descriptions for all modules of the SFR-supporting and SFR-non-interfering
subsystems..
The correspondence information is provided in the form of a spreadsheet
showing the correspondence between the functional specification and the
TOE design.
AGD_OPE.1 A number of documents exist that provide operational guidance for the user
and the system administrators. This includes guides for the overall system
management as well as the management for individual components of z/OS.
Especially for the management of RACF a System Administrator Guide exists,
that describes and explains in detail the administration commands and
parameters.
AGD_PRE.1 Guidance is provided in a number of documents related to the individual
components of z/OS describing the configuration parameter required to
configure the TOE to prepare for a secure operation.
ALC_CMC.4 All configuration management of z/OS source code uses automated CM
systems
ALC_CMS.4 z/OS is developed at different sites each using a well defined and highly
automated configuration management system. Each site has a detailed
description of how the configuration management for the z/OS parts
maintained at the site is performed.
Source code, generated binaries, documentation, test plan, test cases and
test results are all maintained under configuration management.
ALC_DEL.1 z/OS is delivered through sales channels controlled by IBM.
ALC_DVS.1 IBM has a set of guidance documents for physical, logical and procedural
security measures that all IBM facilities have to use in their specific
implementation of a Security Plan. Each site then has their specific Site
Security Plan as a site specific instantiation of those global guidelines.
Several sites of IBM (including for example the site in Poughkeepsie) have
been subject to an analysis of the developer security measures in other
evaluations. Where possible this evaluation will re-use the results of those
evaluations.
ALC_FLR.3 z/OS Development within IBM has a well-defined system for reporting flaws
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and tracing the status of the corrective actions for those flaws. In addition,
well-defined procedures exist for IBM’s z/OS clients to report security
problems via the IBM Support Center, and for IBM to distribute security fixes
to clients, and clients can register with IBM to receive special notification of
security flaws and fixes.
ALC_LCD.1 IBM’s Integrated Product Development (IPD) fulfils the requirements for the
development life cycle model and the life cycle related processes.
ALC_TAT.1 The tools used in the development process and product generation are
documented with their behavior, options and usage assumptions.
ATE_COV.2 IBM has detailed test plans to test the functions of z/OS. Those test plans
include an analysis of the test coverage, an analysis of the functional
interfaces tested and an analysis of the testing against the high level design.
ATE_DPT.1 Testing of internal interfaces is defined and described in the test plan
documents and the test case descriptions.
ATE_FUN.1 Testing has been performed on the platforms that are defined in the Security
Target. Test results are documented such that the tests can be repeated.
ATE_IND.2 All the required resources to perform their own tests will be provided to the
evaluation facility to perform their test. The evaluation facility will perform
and document the tests they have created and performed as part of the
evaluation technical report for testing. Due to the size of the systems the
evaluator tests will be performed at the appropriate IBM development sites.
AVA_VAN.3 IBM has its own team that performs vulnerability analysis and penetration
testing for z/OS. This team has a long term experience with potential security
problems within z/OS and is also integrated in the design reviews. The
developer vulnerability analysis will report the activities and findings of this
team.
Table 21: Assurance measures meeting the TOE security assurance requirements
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9 Abbreviations, Terminology and References
9.1 Abbreviations
ACEE
Accessor Environment Element
AT-TLS
Application-Transparent TLS
CC
Common Criteria
cn
common name
DAC
discretionary access control
DN
distinguished name
IOCDS
input/output configuration data set
LDAP
Lightweight Directory Access Protocol
MAC
mandatory access control
PADS
program access to data sets
PKI
Public Key Infrastructure
PP
Protection Profile
PR/SM
Processor Resource/Systems Manager™
RACF
Resource Access Control Facility
SDSF
System Display and Search Facility
SFR
Security Functional Requirement
TOE
Target of Evaluation
TSF
TOE security functions
TSP
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TOE security policy
9.2 Terminology
This section contains definitions of technical terms that are used with a meaning specific to
this document. Terms defined in the [CC] are not reiterated here, unless stated otherwise.
abstract machine
A processor design that is not intended to be implemented as hardware, but which is
the notional executor of a particular intermediate language (abstract machine
language) used in a compiler or interpreter. An abstract machine has an instruction
set, a register set, and a model of memory. It may provide instructions that are closer
to the language being compiled than any physical computer or it may be used to make
the language implementation easier to port to other platforms.
access
If an authorized user is granted a request to operate on an object, the user is said to
have access to that object. There are numerous types of access. Examples include
read access, which allows the reading of objects, and write access, which allows the
writing of objects.
access control policy
A set of rules used to mediate user access to TOE-protected objects. Access control
policies consist of two types of rules: access rules, which apply to the behavior of
authorized users, and authorization rules, which apply to the behavior of authorized
administrators.
Accessor Environment Element
A RACF control block that describes the current user’s security environment.
authorization
If an authorized user is granted a requested service, the user is said to have
authorization to the requested service or object. There are numerous possible
authorizations. Typical authorizations include auditor authorization, which allows an
administrator to view audit records and execute audit tools, and DAC override
authorization, which allows an administrator to override object access controls to
administer the system.
authorized administrator
An authorized user who has been granted the authority to manage all or a defined
subset of the functions of the TOE. Authorized administrators are expected to use this
authority only in the manner prescribed by the guidance that is given to them.
authorized user
A user who has been properly identified and authenticated. Authorized users are
considered to be legitimate users of the TOE. (Note: this is different from the z/OS
concept of an “authorized program” which is a program running in supervisor state, or
system key, or with APF authority.)
category
See security category.
classification (MLS)
A hierarchical designation for data that represents the sensitivity of the information.
The equivalent IBM term is security level.
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common name (cn)
One component of an LDAP object’s complete name, usually specified as cn=name.
discretionary access control (DAC)
An access control policy that allows authorized users and authorized administrators to
control access to objects based on individual user identity or membership in a group
(PROJECTA, for example).
distinguished name (DN)
The complete name of an object in an LDAP directory, or the complete name of the
subject or issuer of a digital certificate.
Lightweight Directory Access Protocol (LDAP)
A client/server protocol for accessing a directory service.
mandatory access control (MAC)
An access control policy that determines access based on the sensitivity (SECRET, for
example) and category (PERSONNEL or MEDICAL, for example) of the information that
is being accessed and the clearance of the user who is trying to gain access to that
information.
mediation
When DAC and MAC policy rules are invoked, the TOE is said to be mediating access to
TOE-protected objects.
password
For the purposes of this evaluation, a 6 to 8 character secret value used during some
forms of user authentication, and allowing upper- and lower-case alphabetic, numeric,
or national ($, #, @) characters. Passwords are initially assigned by administrators, but
may be changed by the user to whom they are assigned.
password/phrase
A shorthand term for “password or password phrase” sometimes used in this security
target when statements apply equally to passwords or to password phrases.
password phrase
A 14 to 100 character secret value used in a manner similar to a password, except for
its length and an expanded set of valid characters (upper- and lower-case alphabetic,
special (including blanks), or numeric). In addition to assigning a password,
administrators may assign a password phrase to a user.
Note: Phrase may be shorter (down to 9 characters) if enabled by an administrator-
installed exit (ICHPWX11) that RACF supplies.
SECLABEL
Synonym for security label.
SECLEVEL
Synonym for security level (IBM).
security category
A special designation for data at a certain level, which indicates that only people who
have been properly briefed and cleared for access to data with this category can
receive permission for access to the information.
security label
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A name that represents the combination of a hierarchical level of classification
(IBM security level) and a set of non-hierarchical categories (security category).
Security labels are used as the base for mandatory access control decisions. Security
labels are sometimes referred to as SECLABELs.
security level (IBM)
A hierarchical designation for data that represents the sensitivity of the information.
Security levels are sometimes referred to as SECLEVELs. The equivalent MLS term is
classification.
security level (MLS policy in the Bell-LaPadula model)
The combination of a hierarchical classification (called security level in z/OS) and a set
of non-hierarchical categories that represents the sensitivity of information is known as
the security level.
The equivalent term in other IBM documentation is security label.
sensitivity label
A specific marking attached to subjects or objects that indicates the security level. The
equivalent to this MLS term in other IBM documentation is security label.
user
A person who is trying to invoke a service that is offered by the TOE.
user ID
In z/OS, a string of up to eight characters defined as a RACF USER profile that uniquely
identifies a user. Users who may use UNIX services will additionally have a numerical
user identifier (UID) that is used by the UNIX subsystem for access decisions. The user
name is an additional attribute that usually holds the user’s full name. While users can
modify their user names, only administrators can change user IDs.
9.3 References
ABC-V10 ABCs of z/OS System Programming Volume 10
Version SG24-6990-03
Date September 2008
Location http://www.redbooks.ibm.com/redbooks/pdfs/sg246990.pdf
AIS20 Application Notes and Interpretation of the Scheme (AIS)
Version AIS 20, Version 1
Date 2, December, 1999
Location https://www.bsi.bund.de/cae/servlet/contentblob/478152/publicatio
nFile/30552/ais20e_pdf.pdf
CC Common Criteria for Information Technology Security Evaluation
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Version 3.1R3
Date July 2009
Location http://www.commoncriteriaportal.org/files/ccfiles/CCPART1V3.1R3.
pdf
Location http://www.commoncriteriaportal.org/files/ccfiles/CCPART2V3.1R3.
pdf
Location http://www.commoncriteriaportal.org/files/ccfiles/CCPART3V3.1R3.
pdf
OSPP Operating System Protection Profile
Version 2,0
Date 2010-06-01
OSPP-EIA OSPP Extended Package -- Extended Identification and Authentication
Version 2,0
Date 2010-05-28
OSPP-LS OSPP Extended Package -- Labeled Security
Version 2,0
Date 2010-05-28
PMLS z/OS V1R13 Planning for Multilevel Security and the Common Criteria
Version Eleventh Edition
Date June, 2010
File name GA22-7509-10
RFC4217 Securing FTP with TLS
Date
received
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SSHV2 see RFC4251 to RFC4253
Date
received
SSLV3 The SSL Protocol Version 3.0
Date
received
Location http://wp.netscape.com/eng/ssl3/draft302.txt
TLSV1 The TLS Protocol Version 1.0
Date
received
Location ftp://ftp.rfc-editor.org/in-notes/rfc2246.txt
TLSV1.1 See [RFC4346]
Date
received
TLSSEC RFC4492 Elliptic Curve Cryptography (ECC) Cipher Suites for Transport Layer
Security (TLS)
Date
received
ZARCH IBM z/Architecture: Principles of Operation
Version Ninth Edition
Date August, 2010
File name SA22-7832-08
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