| Group
Guide to the Secure Configuration of Oracle Linux 9
Group contains 60 groups and 184 rules |
| Group
System Settings
Group contains 49 groups and 161 rules |
[ref]
Contains rules that check correct system settings. |
| Group
Installing and Maintaining Software
Group contains 9 groups and 30 rules |
[ref]
The following sections contain information on
security-relevant choices during the initial operating system
installation process and the setup of software
updates. |
| Group
System and Software Integrity
Group contains 4 groups and 10 rules |
[ref]
System and software integrity can be gained by installing antivirus, increasing
system encryption strength with FIPS, verifying installed software, enabling SELinux,
installing an Intrusion Prevention System, etc. However, installing or enabling integrity
checking tools cannot prevent intrusions, but they can detect that an intrusion
may have occurred. Requirements for integrity checking may be highly dependent on
the environment in which the system will be used. Snapshot-based approaches such
as AIDE may induce considerable overhead in the presence of frequent software updates. |
| Group
Software Integrity Checking
Group contains 1 group and 1 rule |
[ref]
Both the AIDE (Advanced Intrusion Detection Environment)
software and the RPM package management system provide
mechanisms for verifying the integrity of installed software.
AIDE uses snapshots of file metadata (such as hashes) and compares these
to current system files in order to detect changes.
The RPM package management system can conduct integrity
checks by comparing information in its metadata database with
files installed on the system. |
| Group
Verify Integrity with AIDE
Group contains 1 rule |
[ref]
AIDE conducts integrity checks by comparing information about
files with previously-gathered information. Ideally, the AIDE database is
created immediately after initial system configuration, and then again after any
software update. AIDE is highly configurable, with further configuration
information located in /usr/share/doc/aide-VERSION. |
Rule
Install AIDE
[ref] | The aide package can be installed with the following command:
$ sudo yum install aide | | Rationale: | The AIDE package must be installed if it is to be available for integrity checking. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_aide_installed | | Identifiers and References | References:
BP28(R51), 1, 11, 12, 13, 14, 15, 16, 2, 3, 5, 7, 8, 9, 5.10.1.3, APO01.06, BAI01.06, BAI02.01, BAI03.05, BAI06.01, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS01.03, DSS03.05, DSS04.07, DSS05.02, DSS05.03, DSS05.05, DSS05.07, DSS06.02, DSS06.06, CCI-002696, CCI-002699, CCI-001744, 4.3.4.3.2, 4.3.4.3.3, 4.3.4.4.4, SR 3.1, SR 3.3, SR 3.4, SR 3.8, SR 4.1, SR 6.2, SR 7.6, 1034, 1288, 1341, 1417, A.11.2.4, A.12.1.2, A.12.2.1, A.12.4.1, A.12.5.1, A.12.6.2, A.14.1.2, A.14.1.3, A.14.2.2, A.14.2.3, A.14.2.4, A.14.2.7, A.15.2.1, A.8.2.3, CM-6(a), DE.CM-1, DE.CM-7, PR.DS-1, PR.DS-6, PR.DS-8, PR.IP-1, PR.IP-3, Req-11.5, 11.5.2, SRG-OS-000445-GPOS-00199 | |
|
| Group
Federal Information Processing Standard (FIPS)
Group contains 2 rules |
[ref]
The Federal Information Processing Standard (FIPS) is a computer security standard which
is developed by the U.S. Government and industry working groups to validate the quality
of cryptographic modules. The FIPS standard provides four security levels to ensure
adequate coverage of different industries, implementation of cryptographic modules, and
organizational sizes and requirements.
FIPS 140-2 is the current standard for validating that mechanisms used to access cryptographic modules
utilize authentication that meets industry and government requirements. For government systems, this allows
Security Levels 1, 2, 3, or 4 for use on Oracle Linux 9.
See http://csrc.nist.gov/publications/PubsFIPS.html for more information. |
Rule
Enable Dracut FIPS Module
[ref] | To enable FIPS mode, run the following command:
fips-mode-setup --enable
To enable FIPS, the system requires that the fips module is added in dracut configuration.
Check if /etc/dracut.conf.d/40-fips.conf contain add_dracutmodules+=" fips "Warning:
The system needs to be rebooted for these changes to take effect. Warning:
System Crypto Modules must be provided by a vendor that undergoes FIPS-140 certifications.
FIPS-140 is applicable to all Federal agencies that use cryptographic-based security
systems to protect sensitive information in computer and telecommunication systems
(including voice systems) as defined in Section 5131 of the Information Technology
Management Reform Act of 1996, Public Law 104-106. This standard shall be used in designing
and implementing cryptographic modules that Federal departments and agencies operate or are
operated for them under contract.
See https://nvlpubs.nist.gov/nistpubs/FIPS/NIST.FIPS.140-2.pdf
To meet this, the system has to have cryptographic software provided by a vendor that has
undergone this certification. This means providing documentation, test results, design
information, and independent third party review by an accredited lab. While open source
software is capable of meeting this, it does not meet FIPS-140 unless the vendor submits to
this process. | | Rationale: | Use of weak or untested encryption algorithms undermines the purposes of utilizing encryption to
protect data. The operating system must implement cryptographic modules adhering to the higher
standards approved by the federal government since this provides assurance they have been tested
and validated. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_enable_dracut_fips_module | | Identifiers and References | References:
CCI-000068, CCI-000803, CCI-002450, 1446, CIP-003-8 R4.2, CIP-007-3 R5.1, SC-12(2), SC-12(3), IA-7, SC-13, CM-6(a), SC-12, FCS_RBG_EXT.1, SRG-OS-000478-GPOS-00223 | |
|
Rule
Enable FIPS Mode
[ref] |
To enable FIPS mode, run the following command:
fips-mode-setup --enable
The fips-mode-setup command will configure the system in
FIPS mode by automatically configuring the following:
- Setting the kernel FIPS mode flag (
/proc/sys/crypto/fips_enabled) to 1 - Creating
/etc/system-fips - Setting the system crypto policy in
/etc/crypto-policies/config to FIPS:OSPP - Loading the Dracut
fips module
Warning:
The system needs to be rebooted for these changes to take effect. | | Rationale: | Use of weak or untested encryption algorithms undermines the purposes of utilizing encryption to
protect data. The operating system must implement cryptographic modules adhering to the higher
standards approved by the federal government since this provides assurance they have been tested
and validated. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_enable_fips_mode | | Identifiers and References | References:
CCI-000068, CCI-000803, CCI-002450, 1446, CIP-003-8 R4.2, CIP-007-3 R5.1, CM-3(6), SC-12(2), SC-12(3), IA-7, SC-13, CM-6(a), SC-12, FCS_COP.1(1), FCS_COP.1(2), FCS_COP.1(3), FCS_COP.1(4), FCS_CKM.1, FCS_CKM.2, FCS_TLSC_EXT.1, FCS_RBG_EXT.1, SRG-OS-000478-GPOS-00223, SRG-OS-000396-GPOS-00176 | |
|
| Group
System Cryptographic Policies
Group contains 7 rules |
[ref]
Linux has the capability to centrally configure cryptographic polices. The command
update-crypto-policies is used to set the policy applicable for the various
cryptographic back-ends, such as SSL/TLS libraries. The configured cryptographic
policies will be the default policy used by these backends unless the application
user configures them otherwise. When the system has been configured to use the
centralized cryptographic policies, the administrator is assured that any application
that utilizes the supported backends will follow a policy that adheres to the
configured profile.
Currently the supported backends are:
- GnuTLS library
- OpenSSL library
- NSS library
- OpenJDK
- Libkrb5
- BIND
- OpenSSH
Applications and languages which rely on any of these backends will follow the
system policies as well. Examples are apache httpd, nginx, php, and others. |
|
Rule
Configure BIND to use System Crypto Policy
[ref] | Crypto Policies provide a centralized control over crypto algorithms usage of many packages.
BIND is supported by crypto policy, but the BIND configuration may be
set up to ignore it.
To check that Crypto Policies settings are configured correctly, ensure that the /etc/named.conf
includes the appropriate configuration:
In the options section of /etc/named.conf, make sure that the following line
is not commented out or superseded by later includes:
include "/etc/crypto-policies/back-ends/bind.config"; | | Rationale: | Overriding the system crypto policy makes the behavior of the BIND service violate expectations,
and makes system configuration more fragmented. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_configure_bind_crypto_policy | | Identifiers and References | References:
CIP-003-8 R4.2, CIP-007-3 R5.1, SC-13, SC-12(2), SC-12(3), SRG-OS-000423-GPOS-00187, SRG-OS-000426-GPOS-00190 | |
|
Rule
Configure System Cryptography Policy
[ref] | To configure the system cryptography policy to use ciphers only from the FIPS:OSPP
policy, run the following command:
$ sudo update-crypto-policies --set FIPS:OSPP
The rule checks if settings for selected crypto policy are configured as expected. Configuration files in the /etc/crypto-policies/back-ends are either symlinks to correct files provided by Crypto-policies package or they are regular files in case crypto policy customizations are applied.
Crypto policies may be customized by crypto policy modules, in which case it is delimited from the base policy using a colon. Warning:
The system needs to be rebooted for these changes to take effect. Warning:
System Crypto Modules must be provided by a vendor that undergoes
FIPS-140 certifications.
FIPS-140 is applicable to all Federal agencies that use
cryptographic-based security systems to protect sensitive information
in computer and telecommunication systems (including voice systems) as
defined in Section 5131 of the Information Technology Management Reform
Act of 1996, Public Law 104-106. This standard shall be used in
designing and implementing cryptographic modules that Federal
departments and agencies operate or are operated for them under
contract. See https://nvlpubs.nist.gov/nistpubs/FIPS/NIST.FIPS.140-2.pdf
To meet this, the system has to have cryptographic software provided by
a vendor that has undergone this certification. This means providing
documentation, test results, design information, and independent third
party review by an accredited lab. While open source software is
capable of meeting this, it does not meet FIPS-140 unless the vendor
submits to this process. | | Rationale: | Centralized cryptographic policies simplify applying secure ciphers across an operating system and
the applications that run on that operating system. Use of weak or untested encryption algorithms
undermines the purposes of utilizing encryption to protect data. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_configure_crypto_policy | | Identifiers and References | References:
164.308(a)(4)(i), 164.308(b)(1), 164.308(b)(3), 164.312(e)(1), 164.312(e)(2)(ii), 1446, CIP-003-8 R4.2, CIP-007-3 R5.1, CIP-007-3 R7.1, AC-17(a), AC-17(2), CM-6(a), MA-4(6), SC-13, SC-12(2), SC-12(3), FCS_COP.1(1), FCS_COP.1(2), FCS_COP.1(3), FCS_COP.1(4), FCS_CKM.1, FCS_CKM.2, FCS_TLSC_EXT.1, SRG-OS-000396-GPOS-00176, SRG-OS-000393-GPOS-00173, SRG-OS-000394-GPOS-00174 | |
|
Rule
Configure Kerberos to use System Crypto Policy
[ref] | Crypto Policies provide a centralized control over crypto algorithms usage of many packages.
Kerberos is supported by crypto policy, but it's configuration may be
set up to ignore it.
To check that Crypto Policies settings for Kerberos are configured correctly, examine that there is a symlink at
/etc/krb5.conf.d/crypto-policies targeting /etc/cypto-policies/back-ends/krb5.config.
If the symlink exists, Kerberos is configured to use the system-wide crypto policy settings. | | Rationale: | Overriding the system crypto policy makes the behavior of Kerberos violate expectations,
and makes system configuration more fragmented. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_configure_kerberos_crypto_policy | | Identifiers and References | References:
0418, 1055, 1402, CIP-003-8 R4.2, CIP-007-3 R5.1, SC-13, SC-12(2), SC-12(3), SRG-OS-000120-GPOS-00061 | |
|
Rule
Configure Libreswan to use System Crypto Policy
[ref] | Crypto Policies provide a centralized control over crypto algorithms usage of many packages.
Libreswan is supported by system crypto policy, but the Libreswan configuration may be
set up to ignore it.
To check that Crypto Policies settings are configured correctly, ensure that the /etc/ipsec.conf
includes the appropriate configuration file.
In /etc/ipsec.conf, make sure that the following line
is not commented out or superseded by later includes:
include /etc/crypto-policies/back-ends/libreswan.config | | Rationale: | Overriding the system crypto policy makes the behavior of the Libreswan
service violate expectations, and makes system configuration more
fragmented. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_configure_libreswan_crypto_policy | | Identifiers and References | References:
CIP-003-8 R4.2, CIP-007-3 R5.1, CM-6(a), MA-4(6), SC-13, SC-12(2), SC-12(3), FCS_IPSEC_EXT.1.4, FCS_IPSEC_EXT.1.6, Req-2.2, 2.2, SRG-OS-000033-GPOS-00014 | |
|
Rule
Configure OpenSSL library to use System Crypto Policy
[ref] | Crypto Policies provide a centralized control over crypto algorithms usage of many packages.
OpenSSL is supported by crypto policy, but the OpenSSL configuration may be
set up to ignore it.
To check that Crypto Policies settings are configured correctly, you have to examine the OpenSSL config file
available under /etc/pki/tls/openssl.cnf.
This file has the ini format, and it enables crypto policy support
if there is a [ crypto_policy ] section that contains the .include = /etc/crypto-policies/back-ends/opensslcnf.config directive. | | Rationale: | Overriding the system crypto policy makes the behavior of the Java runtime violates expectations,
and makes system configuration more fragmented. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_configure_openssl_crypto_policy | | Identifiers and References | References:
CCI-001453, CIP-003-8 R4.2, CIP-007-3 R5.1, CIP-007-3 R7.1, AC-17(a), AC-17(2), CM-6(a), MA-4(6), SC-13, SC-12(2), SC-12(3), Req-2.2, 2.2, SRG-OS-000250-GPOS-00093 | |
|
Rule
Configure SSH to use System Crypto Policy
[ref] | Crypto Policies provide a centralized control over crypto algorithms usage of many packages.
SSH is supported by crypto policy, but the SSH configuration may be
set up to ignore it.
To check that Crypto Policies settings are configured correctly, ensure that
the CRYPTO_POLICY variable is either commented or not set at all
in the /etc/sysconfig/sshd. | | Rationale: | Overriding the system crypto policy makes the behavior of the SSH service violate expectations,
and makes system configuration more fragmented. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_configure_ssh_crypto_policy | | Identifiers and References | References:
CCI-001453, 164.308(a)(4)(i), 164.308(b)(1), 164.308(b)(3), 164.312(e)(1), 164.312(e)(2)(ii), CIP-003-8 R4.2, CIP-007-3 R5.1, CIP-007-3 R7.1, AC-17(a), AC-17(2), CM-6(a), MA-4(6), SC-13, FCS_SSH_EXT.1, FCS_SSHS_EXT.1, FCS_SSHC_EXT.1, Req-2.2, 2.2, SRG-OS-000250-GPOS-00093 | |
|
| Group
Disk Partitioning
Group contains 5 rules |
[ref]
To ensure separation and protection of data, there
are top-level system directories which should be placed on their
own physical partition or logical volume. The installer's default
partitioning scheme creates separate logical volumes for
/, /boot, and swap.
- If starting with any of the default layouts, check the box to
\"Review and modify partitioning.\" This allows for the easy creation
of additional logical volumes inside the volume group already
created, though it may require making
/'s logical volume smaller to
create space. In general, using logical volumes is preferable to
using partitions because they can be more easily adjusted
later. - If creating a custom layout, create the partitions mentioned in
the previous paragraph (which the installer will require anyway),
as well as separate ones described in the following sections.
If a system has already been installed, and the default
partitioning
scheme was used, it is possible but nontrivial to
modify it to create separate logical volumes for the directories
listed above. The Logical Volume Manager (LVM) makes this possible.
See the LVM HOWTO at
http://tldp.org/HOWTO/LVM-HOWTO/
for more detailed information on LVM. |
Rule
Ensure /home Located On Separate Partition
[ref] | If user home directories will be stored locally, create a separate partition
for /home at installation time (or migrate it later using LVM). If
/home will be mounted from another system such as an NFS server, then
creating a separate partition is not necessary at installation time, and the
mountpoint can instead be configured later. | | Rationale: | Ensuring that /home is mounted on its own partition enables the
setting of more restrictive mount options, and also helps ensure that
users cannot trivially fill partitions used for log or audit data storage. | | Severity: | low | | Rule ID: | xccdf_org.ssgproject.content_rule_partition_for_home | | Identifiers and References | References:
BP28(R12), 12, 15, 8, APO13.01, DSS05.02, CCI-000366, CCI-001208, SR 3.1, SR 3.5, SR 3.8, SR 4.1, SR 4.3, SR 5.1, SR 5.2, SR 5.3, SR 7.1, SR 7.6, A.13.1.1, A.13.2.1, A.14.1.3, CM-6(a), SC-5(2), PR.PT-4, SRG-OS-000480-GPOS-00227 | |
|
Rule
Ensure /var Located On Separate Partition
[ref] | The /var directory is used by daemons and other system
services to store frequently-changing data. Ensure that /var has its own partition
or logical volume at installation time, or migrate it using LVM. | | Rationale: | Ensuring that /var is mounted on its own partition enables the
setting of more restrictive mount options. This helps protect
system services such as daemons or other programs which use it.
It is not uncommon for the /var directory to contain
world-writable directories installed by other software packages. | | Severity: | low | | Rule ID: | xccdf_org.ssgproject.content_rule_partition_for_var | | Identifiers and References | References:
BP28(R12), 12, 15, 8, APO13.01, DSS05.02, CCI-000366, SR 3.1, SR 3.5, SR 3.8, SR 4.1, SR 4.3, SR 5.1, SR 5.2, SR 5.3, SR 7.1, SR 7.6, A.13.1.1, A.13.2.1, A.14.1.3, CM-6(a), SC-5(2), PR.PT-4, SRG-OS-000480-GPOS-00227 | |
|
Rule
Ensure /var/log Located On Separate Partition
[ref] | System logs are stored in the /var/log directory.
Ensure that /var/log has its own partition or logical
volume at installation time, or migrate it using LVM. | | Rationale: | Placing /var/log in its own partition
enables better separation between log files
and other files in /var/. | | Severity: | low | | Rule ID: | xccdf_org.ssgproject.content_rule_partition_for_var_log | | Identifiers and References | References:
BP28(R12), BP28(R47), 1, 12, 14, 15, 16, 3, 5, 6, 8, APO11.04, APO13.01, BAI03.05, DSS05.02, DSS05.04, DSS05.07, MEA02.01, CCI-000366, 4.3.3.3.9, 4.3.3.5.8, 4.3.4.4.7, 4.4.2.1, 4.4.2.2, 4.4.2.4, SR 2.10, SR 2.11, SR 2.12, SR 2.8, SR 2.9, SR 3.1, SR 3.5, SR 3.8, SR 4.1, SR 4.3, SR 5.1, SR 5.2, SR 5.3, SR 7.1, SR 7.6, A.12.4.1, A.12.4.2, A.12.4.3, A.12.4.4, A.12.7.1, A.13.1.1, A.13.2.1, A.14.1.3, CIP-007-3 R6.5, CM-6(a), AU-4, SC-5(2), PR.PT-1, PR.PT-4, SRG-OS-000480-GPOS-00227 | |
|
Rule
Ensure /var/log/audit Located On Separate Partition
[ref] | Audit logs are stored in the /var/log/audit directory.
Ensure that /var/log/audit has its own partition or logical
volume at installation time, or migrate it using LVM.
Make absolutely certain that it is large enough to store all
audit logs that will be created by the auditing daemon. | | Rationale: | Placing /var/log/audit in its own partition
enables better separation between audit files
and other files, and helps ensure that
auditing cannot be halted due to the partition running out
of space. | | Severity: | low | | Rule ID: | xccdf_org.ssgproject.content_rule_partition_for_var_log_audit | | Identifiers and References | References:
BP28(R43), 1, 12, 13, 14, 15, 16, 2, 3, 5, 6, 8, APO11.04, APO13.01, BAI03.05, BAI04.04, DSS05.02, DSS05.04, DSS05.07, MEA02.01, CCI-000366, CCI-001849, 164.312(a)(2)(ii), 4.3.3.3.9, 4.3.3.5.8, 4.3.4.4.7, 4.4.2.1, 4.4.2.2, 4.4.2.4, SR 2.10, SR 2.11, SR 2.12, SR 2.8, SR 2.9, SR 3.1, SR 3.5, SR 3.8, SR 4.1, SR 4.3, SR 5.1, SR 5.2, SR 5.3, SR 7.1, SR 7.2, SR 7.6, A.12.1.3, A.12.4.1, A.12.4.2, A.12.4.3, A.12.4.4, A.12.7.1, A.13.1.1, A.13.2.1, A.14.1.3, A.17.2.1, CIP-007-3 R6.5, CM-6(a), AU-4, SC-5(2), PR.DS-4, PR.PT-1, PR.PT-4, FMT_SMF_EXT.1, SRG-OS-000341-GPOS-00132, SRG-OS-000480-GPOS-00227, SRG-APP-000357-CTR-000800 | |
|
Rule
Ensure /var/tmp Located On Separate Partition
[ref] | The /var/tmp directory is a world-writable directory used
for temporary file storage. Ensure it has its own partition or
logical volume at installation time, or migrate it using LVM. | | Rationale: | The /var/tmp partition is used as temporary storage by many programs.
Placing /var/tmp in its own partition enables the setting of more
restrictive mount options, which can help protect programs which use it. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_partition_for_var_tmp | | Identifiers and References | References:
BP28(R12), SRG-OS-000480-GPOS-00227 | |
|
| Group
Sudo
Group contains 1 rule |
[ref]
Sudo, which stands for "su 'do'", provides the ability to delegate authority
to certain users, groups of users, or system administrators. When configured for system
users and/or groups, Sudo can allow a user or group to execute privileged commands
that normally only root is allowed to execute.
For more information on Sudo and addition Sudo configuration options, see
https://www.sudo.ws. |
Rule
Install sudo Package
[ref] | The sudo package can be installed with the following command:
$ sudo yum install sudo | | Rationale: | sudo is a program designed to allow a system administrator to give
limited root privileges to users and log root activity. The basic philosophy
is to give as few privileges as possible but still allow system users to
get their work done.
| | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_sudo_installed | | Identifiers and References | References:
BP28(R19), 1382, 1384, 1386, CM-6(a), FMT_MOF_EXT.1, 10.2.1.5, SRG-OS-000324-GPOS-00125 | |
|
| Group
System Tooling / Utilities
Group contains 6 rules |
[ref]
The following checks evaluate the system for recommended base packages -- both for installation
and removal. |
Rule
Ensure gnutls-utils is installed
[ref] | The gnutls-utils package can be installed with the following command:
$ sudo yum install gnutls-utils | | Rationale: | GnuTLS is a secure communications library implementing the SSL, TLS and DTLS
protocols and technologies around them. It provides a simple C language
application programming interface (API) to access the secure communications
protocols as well as APIs to parse and write X.509, PKCS #12, OpenPGP and
other required structures.
This package contains command line TLS client and server and certificate
manipulation tools. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_gnutls-utils_installed | | Identifiers and References | References:
FIA_X509_EXT.1, FIA_X509_EXT.2, SRG-OS-000480-GPOS-00227 | |
|
Rule
Install openscap-scanner Package
[ref] | The openscap-scanner package can be installed with the following command:
$ sudo yum install openscap-scanner | | Rationale: | openscap-scanner contains the oscap command line tool. This tool is a
configuration and vulnerability scanner, capable of performing compliance checking using
SCAP content.
| | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_openscap-scanner_installed | | Identifiers and References | References:
AGD_PRE.1, AGD_OPE.1, SRG-OS-000480-GPOS-00227, SRG-OS-000191-GPOS-00080 | |
|
Rule
Install scap-security-guide Package
[ref] | The scap-security-guide package can be installed with the following command:
$ sudo yum install scap-security-guide | | Rationale: | The scap-security-guide package provides a guide for configuration of the system
from the final system's security point of view. The guidance is specified in the Security
Content Automation Protocol (SCAP) format and constitutes a catalog of practical hardening
advice, linked to government requirements where applicable. The SCAP Security Guide project
bridges the gap between generalized policy requirements and specific implementation guidelines.
A system administrator can use the oscap CLI tool from the openscap-scanner
package, or the SCAP Workbench GUI tool from the scap-workbench package, to verify
that the system conforms to provided guidelines. Refer to the scap-security-guide(8) manual
page for futher information. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_scap-security-guide_installed | | Identifiers and References | References:
AGD_PRE.1, AGD_OPE.1, SRG-OS-000480-GPOS-00227 | |
|
Rule
Uninstall gssproxy Package
[ref] | The gssproxy package can be removed with the following command:
$ sudo yum erase gssproxy | | Rationale: | gssproxy is a proxy for GSS API credential handling.
| | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_gssproxy_removed | | Identifiers and References | References:
CCI-000381, CCI-000366, SRG-OS-000095-GPOS-00049, SRG-OS-000480-GPOS-00227 | |
|
Rule
Uninstall iprutils Package
[ref] | The iprutils package can be removed with the following command:
$ sudo yum erase iprutils | | Rationale: | iprutils provides a suite of utlilities to manage and configure SCSI devices
supported by the ipr SCSI storage device driver.
| | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_iprutils_removed | | Identifiers and References | References:
CCI-000366, SRG-OS-000095-GPOS-00049, SRG-OS-000480-GPOS-00227 | |
|
Rule
Uninstall krb5-workstation Package
[ref] | The krb5-workstation package can be removed with the following command:
$ sudo yum erase krb5-workstation | | Rationale: | Kerberos is a network authentication system. The krb5-workstation package contains the basic
Kerberos programs (kinit, klist, kdestroy, kpasswd). | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_krb5-workstation_removed | | Identifiers and References | References:
CCI-000803, SRG-OS-000095-GPOS-00049, SRG-OS-000120-GPOS-00061 | |
|
| Group
Updating Software
Group contains 8 rules |
[ref]
The yum command line tool is used to install and
update software packages. The system also provides a graphical
software update tool in the System menu, in the Administration submenu,
called Software Update.
Oracle Linux 9 systems contain an installed software catalog called
the RPM database, which records metadata of installed packages. Consistently using
yum or the graphical Software Update for all software installation
allows for insight into the current inventory of installed software on the system.
|
Rule
Install dnf-automatic Package
[ref] | The dnf-automatic package can be installed with the following command:
$ sudo yum install dnf-automatic | | Rationale: | dnf-automatic is an alternative command line interface (CLI)
to dnf upgrade suitable for automatic, regular execution.
| | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_dnf-automatic_installed | | Identifiers and References | References:
BP28(R8), SRG-OS-000191-GPOS-00080 | |
|
Rule
Configure dnf-automatic to Install Available Updates Automatically
[ref] | To ensure that the packages comprising the available updates will be automatically installed by dnf-automatic, set apply_updates to yes under [commands] section in /etc/dnf/automatic.conf. | | Rationale: | Installing software updates is a fundamental mitigation against
the exploitation of publicly-known vulnerabilities. If the most
recent security patches and updates are not installed, unauthorized
users may take advantage of weaknesses in the unpatched software. The
lack of prompt attention to patching could result in a system compromise.
The automated installation of updates ensures that recent security patches
are applied in a timely manner. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_dnf-automatic_apply_updates | | Identifiers and References | References:
BP28(R8), 0940, 1144, 1467, 1472, 1483, 1493, 1494, 1495, SI-2(5), CM-6(a), SI-2(c), FMT_SMF_EXT.1, SRG-OS-000191-GPOS-00080 | |
|
Rule
Configure dnf-automatic to Install Only Security Updates
[ref] | To configure dnf-automatic to install only security updates
automatically, set upgrade_type to security under
[commands] section in /etc/dnf/automatic.conf. | | Rationale: | By default, dnf-automatic installs all available updates.
Reducing the amount of updated packages only to updates that were
issued as a part of a security advisory increases the system stability. | | Severity: | low | | Rule ID: | xccdf_org.ssgproject.content_rule_dnf-automatic_security_updates_only | | Identifiers and References | References:
BP28(R8), SI-2(5), CM-6(a), SI-2(c), FMT_SMF_EXT.1, SRG-OS-000191-GPOS-00080 | |
|
Rule
Ensure gpgcheck Enabled In Main yum Configuration
[ref] | The gpgcheck option controls whether
RPM packages' signatures are always checked prior to installation.
To configure yum to check package signatures before installing
them, ensure the following line appears in /etc/yum.conf in
the [main] section:
gpgcheck=1 | | Rationale: | Changes to any software components can have significant effects on the
overall security of the operating system. This requirement ensures the
software has not been tampered with and that it has been provided by a
trusted vendor.
Accordingly, patches, service packs, device drivers, or operating system
components must be signed with a certificate recognized and approved by the
organization.
Verifying the authenticity of the software prior to installation
validates the integrity of the patch or upgrade received from a vendor.
This ensures the software has not been tampered with and that it has been
provided by a trusted vendor. Self-signed certificates are disallowed by
this requirement. Certificates used to verify the software must be from an
approved Certificate Authority (CA). | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_ensure_gpgcheck_globally_activated | | Identifiers and References | References:
BP28(R15), 11, 2, 3, 9, 5.10.4.1, APO01.06, BAI03.05, BAI06.01, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS06.02, 3.4.8, CCI-001749, 164.308(a)(1)(ii)(D), 164.312(b), 164.312(c)(1), 164.312(c)(2), 164.312(e)(2)(i), 4.3.4.3.2, 4.3.4.3.3, 4.3.4.4.4, SR 3.1, SR 3.3, SR 3.4, SR 3.8, SR 7.6, A.11.2.4, A.12.1.2, A.12.2.1, A.12.5.1, A.12.6.2, A.14.1.2, A.14.1.3, A.14.2.2, A.14.2.3, A.14.2.4, CM-5(3), SI-7, SC-12, SC-12(3), CM-6(a), SA-12, SA-12(10), CM-11(a), CM-11(b), PR.DS-6, PR.DS-8, PR.IP-1, FPT_TUD_EXT.1, FPT_TUD_EXT.2, Req-6.2, 6.3.3, SRG-OS-000366-GPOS-00153 | |
|
Rule
Ensure gpgcheck Enabled for Local Packages
[ref] | yum should be configured to verify the signature(s) of local packages
prior to installation. To configure yum to verify signatures of local
packages, set the localpkg_gpgcheck to 1 in /etc/yum.conf.
| | Rationale: | Changes to any software components can have significant effects to the overall security
of the operating system. This requirement ensures the software has not been tampered and
has been provided by a trusted vendor.
Accordingly, patches, service packs, device drivers, or operating system components must
be signed with a certificate recognized and approved by the organization. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_ensure_gpgcheck_local_packages | | Identifiers and References | References:
BP28(R15), 11, 3, 9, BAI10.01, BAI10.02, BAI10.03, BAI10.05, 3.4.8, CCI-001749, 164.308(a)(1)(ii)(D), 164.312(b), 164.312(c)(1), 164.312(c)(2), 164.312(e)(2)(i), 4.3.4.3.2, 4.3.4.3.3, SR 7.6, A.12.1.2, A.12.5.1, A.12.6.2, A.14.2.2, A.14.2.3, A.14.2.4, CM-11(a), CM-11(b), CM-6(a), CM-5(3), SA-12, SA-12(10), PR.IP-1, FPT_TUD_EXT.1, FPT_TUD_EXT.2, SRG-OS-000366-GPOS-00153 | |
|
Rule
Ensure gpgcheck Enabled for All yum Package Repositories
[ref] | To ensure signature checking is not disabled for
any repos, remove any lines from files in /etc/yum.repos.d of the form:
gpgcheck=0 | | Rationale: | Verifying the authenticity of the software prior to installation validates
the integrity of the patch or upgrade received from a vendor. This ensures
the software has not been tampered with and that it has been provided by a
trusted vendor. Self-signed certificates are disallowed by this
requirement. Certificates used to verify the software must be from an
approved Certificate Authority (CA)." | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_ensure_gpgcheck_never_disabled | | Identifiers and References | References:
BP28(R15), 11, 2, 3, 9, 5.10.4.1, APO01.06, BAI03.05, BAI06.01, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS06.02, 3.4.8, CCI-001749, 164.308(a)(1)(ii)(D), 164.312(b), 164.312(c)(1), 164.312(c)(2), 164.312(e)(2)(i), 4.3.4.3.2, 4.3.4.3.3, 4.3.4.4.4, SR 3.1, SR 3.3, SR 3.4, SR 3.8, SR 7.6, A.11.2.4, A.12.1.2, A.12.2.1, A.12.5.1, A.12.6.2, A.14.1.2, A.14.1.3, A.14.2.2, A.14.2.3, A.14.2.4, CM-5(3), SI-7, SC-12, SC-12(3), CM-6(a), SA-12, SA-12(10), CM-11(a), CM-11(b), PR.DS-6, PR.DS-8, PR.IP-1, FPT_TUD_EXT.1, FPT_TUD_EXT.2, Req-6.2, 6.3.3, SRG-OS-000366-GPOS-00153 | |
|
Rule
Ensure Oracle Linux GPG Key Installed
[ref] | To ensure the system can cryptographically verify base software
packages come from Oracle (and to connect to the Unbreakable Linux Network to
receive them), the Oracle GPG key must properly be installed.
To install the Oracle GPG key, run:
$ sudo uln_register
If the system is not connected to the Internet,
then install the Oracle GPG key from trusted media such as
the Oracle installation CD-ROM or DVD. Assuming the disc is mounted
in /media/cdrom, use the following command as the root user to import
it into the keyring:
$ sudo rpm --import /media/cdrom/RPM-GPG-KEY-oracle
Alternatively, the key may be pre-loaded during the Oracle installation. In
such cases, the key can be installed by running the following command:
sudo rpm --import /etc/pki/rpm-gpg/RPM-GPG-KEY-oracle | | Rationale: | Changes to software components can have significant effects on the
overall security of the operating system. This requirement ensures
the software has not been tampered with and that it has been provided
by a trusted vendor. The Oracle GPG key is necessary to
cryptographically verify packages are from Oracle. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_ensure_oracle_gpgkey_installed | | Identifiers and References | References:
11, 2, 3, 9, APO01.06, BAI03.05, BAI06.01, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS06.02, CCI-001749, 4.3.4.3.2, 4.3.4.3.3, 4.3.4.4.4, SR 3.1, SR 3.3, SR 3.4, SR 3.8, SR 7.6, A.11.2.4, A.12.1.2, A.12.2.1, A.12.5.1, A.12.6.2, A.14.1.2, A.14.1.3, A.14.2.2, A.14.2.3, A.14.2.4, CM-5(3), SI-7, SC-12, SC-12(3), CM-6(a), CM-11(a), CM-11(b), PR.DS-6, PR.DS-8, PR.IP-1, Req-6.2 | |
|
Rule
Enable dnf-automatic Timer
[ref] |
The dnf-automatic timer can be enabled with the following command:
$ sudo systemctl enable dnf-automatic.timer | | Rationale: | The dnf-automatic is an alternative command line interface (CLI) to dnf upgrade with specific facilities to make it suitable to be executed automatically and regularly from systemd timers, cron jobs and similar.
The tool is controlled by dnf-automatic.timer SystemD timer. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_timer_dnf-automatic_enabled | | Identifiers and References | References:
BP28(R8), SI-2(5), CM-6(a), SI-2(c), FMT_SMF_EXT.1, SRG-OS-000191-GPOS-00080 | |
|
| Group
Account and Access Control
Group contains 13 groups and 30 rules |
[ref]
In traditional Unix security, if an attacker gains
shell access to a certain login account, they can perform any action
or access any file to which that account has access. Therefore,
making it more difficult for unauthorized people to gain shell
access to accounts, particularly to privileged accounts, is a
necessary part of securing a system. This section introduces
mechanisms for restricting access to accounts under
Oracle Linux 9. |
| Group
Protect Accounts by Configuring PAM
Group contains 3 groups and 12 rules |
[ref]
PAM, or Pluggable Authentication Modules, is a system
which implements modular authentication for Linux programs. PAM provides
a flexible and configurable architecture for authentication, and it should be configured
to minimize exposure to unnecessary risk. This section contains
guidance on how to accomplish that.
PAM is implemented as a set of shared objects which are
loaded and invoked whenever an application wishes to authenticate a
user. Typically, the application must be running as root in order
to take advantage of PAM, because PAM's modules often need to be able
to access sensitive stores of account information, such as /etc/shadow.
Traditional privileged network listeners
(e.g. sshd) or SUID programs (e.g. sudo) already meet this
requirement. An SUID root application, userhelper, is provided so
that programs which are not SUID or privileged themselves can still
take advantage of PAM.
PAM looks in the directory /etc/pam.d for
application-specific configuration information. For instance, if
the program login attempts to authenticate a user, then PAM's
libraries follow the instructions in the file /etc/pam.d/login
to determine what actions should be taken.
One very important file in /etc/pam.d is
/etc/pam.d/system-auth. This file, which is included by
many other PAM configuration files, defines 'default' system authentication
measures. Modifying this file is a good way to make far-reaching
authentication changes, for instance when implementing a
centralized authentication service. Warning:
Be careful when making changes to PAM's configuration files.
The syntax for these files is complex, and modifications can
have unexpected consequences. The default configurations shipped
with applications should be sufficient for most users. |
| Group
Set Lockouts for Failed Password Attempts
Group contains 4 rules |
[ref]
The pam_faillock PAM module provides the capability to
lock out user accounts after a number of failed login attempts. Its
documentation is available in
/usr/share/doc/pam-VERSION/txts/README.pam_faillock.
Warning:
Locking out user accounts presents the
risk of a denial-of-service attack. The lockout policy
must weigh whether the risk of such a
denial-of-service attack outweighs the benefits of thwarting
password guessing attacks. |
Rule
Limit Password Reuse
[ref] | Do not allow users to reuse recent passwords. This can be accomplished by using the
remember option for the pam_unix or pam_pwhistory PAM modules. Warning:
If the system relies on authselect tool to manage PAM settings, the remediation
will also use authselect tool. However, if any manual modification was made in
PAM files, the authselect integrity check will fail and the remediation will be
aborted in order to preserve intentional changes. In this case, an informative message will
be shown in the remediation report. Warning:
Newer versions of authselect contain an authselect feature to easily and properly
enable pam_pwhistory.so module. If this feature is not yet available in your
system, an authselect custom profile must be used to avoid integrity issues in PAM files. | | Rationale: | Preventing re-use of previous passwords helps ensure that a compromised password is not
re-used by a user. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_pam_unix_remember | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, 5, 5.6.2.1.1, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, 3.5.8, CCI-000200, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(f), IA-5(1)(e), PR.AC-1, PR.AC-6, PR.AC-7, Req-8.2.5, 8.3.7, SRG-OS-000077-GPOS-00045 | |
|
Rule
Lock Accounts After Failed Password Attempts
[ref] | This rule configures the system to lock out accounts after a number of incorrect login attempts
using pam_faillock.so.
pam_faillock.so module requires multiple entries in pam files. These entries must be carefully
defined to work as expected.
Ensure that the file /etc/security/faillock.conf contains the following entry:
deny = <count>
Where count should be less than or equal to
3 and greater than 0.
In order to avoid errors when manually editing these files, it is
recommended to use the appropriate tools, such as authselect or authconfig,
depending on the OS version. Warning:
If the system relies on authselect tool to manage PAM settings, the remediation
will also use authselect tool. However, if any manual modification was made in
PAM files, the authselect integrity check will fail and the remediation will be
aborted in order to preserve intentional changes. In this case, an informative message will
be shown in the remediation report.
If the system supports the /etc/security/faillock.conf file, the pam_faillock
parameters should be defined in faillock.conf file. | | Rationale: | By limiting the number of failed logon attempts, the risk of unauthorized system access via
user password guessing, also known as brute-forcing, is reduced. Limits are imposed by locking
the account. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_passwords_pam_faillock_deny | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, 5.5.3, DSS05.04, DSS05.10, DSS06.10, 3.1.8, CCI-000044, CCI-002236, CCI-002237, CCI-002238, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, SR 1.1, SR 1.10, SR 1.2, SR 1.5, SR 1.7, SR 1.8, SR 1.9, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.9.2.1, A.9.2.4, A.9.3.1, A.9.4.2, A.9.4.3, CM-6(a), AC-7(a), PR.AC-7, FIA_AFL.1, Req-8.1.6, 8.3.4, SRG-OS-000329-GPOS-00128, SRG-OS-000021-GPOS-00005 | |
|
Rule
Set Interval For Counting Failed Password Attempts
[ref] | Utilizing pam_faillock.so, the fail_interval directive configures the system
to lock out an account after a number of incorrect login attempts within a specified time
period.
Ensure that the file /etc/security/faillock.conf contains the following entry:
fail_interval = <interval-in-seconds> where interval-in-seconds is 900 or greater.
In order to avoid errors when manually editing these files, it is
recommended to use the appropriate tools, such as authselect or authconfig,
depending on the OS version. Warning:
If the system relies on authselect tool to manage PAM settings, the remediation
will also use authselect tool. However, if any manual modification was made in
PAM files, the authselect integrity check will fail and the remediation will be
aborted in order to preserve intentional changes. In this case, an informative message will
be shown in the remediation report.
If the system supports the /etc/security/faillock.conf file, the pam_faillock
parameters should be defined in faillock.conf file. | | Rationale: | By limiting the number of failed logon attempts the risk of unauthorized system
access via user password guessing, otherwise known as brute-forcing, is reduced.
Limits are imposed by locking the account. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_passwords_pam_faillock_interval | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, DSS05.04, DSS05.10, DSS06.10, CCI-000044, CCI-002236, CCI-002237, CCI-002238, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, SR 1.1, SR 1.10, SR 1.2, SR 1.5, SR 1.7, SR 1.8, SR 1.9, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.9.2.1, A.9.2.4, A.9.3.1, A.9.4.2, A.9.4.3, CM-6(a), AC-7(a), PR.AC-7, FIA_AFL.1, SRG-OS-000329-GPOS-00128, SRG-OS-000021-GPOS-00005 | |
|
Rule
Set Lockout Time for Failed Password Attempts
[ref] | This rule configures the system to lock out accounts during a specified time period after a
number of incorrect login attempts using pam_faillock.so.
Ensure that the file /etc/security/faillock.conf contains the following entry:
unlock_time=<interval-in-seconds> where
interval-in-seconds is 0 or greater.
pam_faillock.so module requires multiple entries in pam files. These entries must be carefully
defined to work as expected. In order to avoid any errors when manually editing these files,
it is recommended to use the appropriate tools, such as authselect or authconfig,
depending on the OS version.
If unlock_time is set to 0, manual intervention by an administrator is required
to unlock a user. This should be done using the faillock tool. Warning:
If the system supports the new /etc/security/faillock.conf file but the
pam_faillock.so parameters are defined directly in /etc/pam.d/system-auth and
/etc/pam.d/password-auth, the remediation will migrate the unlock_time parameter
to /etc/security/faillock.conf to ensure compatibility with authselect tool.
The parameters deny and fail_interval, if used, also have to be migrated
by their respective remediation. Warning:
If the system relies on authselect tool to manage PAM settings, the remediation
will also use authselect tool. However, if any manual modification was made in
PAM files, the authselect integrity check will fail and the remediation will be
aborted in order to preserve intentional changes. In this case, an informative message will
be shown in the remediation report.
If the system supports the /etc/security/faillock.conf file, the pam_faillock
parameters should be defined in faillock.conf file. | | Rationale: | By limiting the number of failed logon attempts the risk of unauthorized system
access via user password guessing, otherwise known as brute-forcing, is reduced.
Limits are imposed by locking the account. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_passwords_pam_faillock_unlock_time | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, 5.5.3, DSS05.04, DSS05.10, DSS06.10, 3.1.8, CCI-000044, CCI-002236, CCI-002237, CCI-002238, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, SR 1.1, SR 1.10, SR 1.2, SR 1.5, SR 1.7, SR 1.8, SR 1.9, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.9.2.1, A.9.2.4, A.9.3.1, A.9.4.2, A.9.4.3, CM-6(a), AC-7(b), PR.AC-7, FIA_AFL.1, Req-8.1.7, 8.3.4, SRG-OS-000329-GPOS-00128, SRG-OS-000021-GPOS-00005 | |
|
| Group
Set Password Quality Requirements
Group contains 1 group and 8 rules |
[ref]
The default pam_pwquality PAM module provides strength
checking for passwords. It performs a number of checks, such as
making sure passwords are not similar to dictionary words, are of
at least a certain length, are not the previous password reversed,
and are not simply a change of case from the previous password. It
can also require passwords to be in certain character classes. The
pam_pwquality module is the preferred way of configuring
password requirements.
The man pages pam_pwquality(8)
provide information on the capabilities and configuration of
each. |
| Group
Set Password Quality Requirements with pam_pwquality
Group contains 8 rules |
[ref]
The pam_pwquality PAM module can be configured to meet
requirements for a variety of policies.
For example, to configure pam_pwquality to require at least one uppercase
character, lowercase character, digit, and other (special)
character, make sure that pam_pwquality exists in /etc/pam.d/system-auth:
password requisite pam_pwquality.so try_first_pass local_users_only retry=3 authtok_type=
If no such line exists, add one as the first line of the password section in /etc/pam.d/system-auth.
Next, modify the settings in /etc/security/pwquality.conf to match the following:
difok = 4
minlen = 14
dcredit = -1
ucredit = -1
lcredit = -1
ocredit = -1
maxrepeat = 3
The arguments can be modified to ensure compliance with
your organization's security policy. Discussion of each parameter follows. |
Rule
Ensure PAM Enforces Password Requirements - Minimum Digit Characters
[ref] | The pam_pwquality module's dcredit parameter controls requirements for
usage of digits in a password. When set to a negative number, any password will be required to
contain that many digits. When set to a positive number, pam_pwquality will grant +1 additional
length credit for each digit. Modify the dcredit setting in
/etc/security/pwquality.conf to require the use of a digit in passwords. | | Rationale: | Use of a complex password helps to increase the time and resources required
to compromise the password. Password complexity, or strength, is a measure of
the effectiveness of a password in resisting attempts at guessing and brute-force
attacks.
Password complexity is one factor of several that determines how long it takes
to crack a password. The more complex the password, the greater the number of
possible combinations that need to be tested before the password is compromised.
Requiring digits makes password guessing attacks more difficult by ensuring a larger
search space. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_pam_dcredit | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, 5, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, CCI-000194, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(c), IA-5(1)(a), CM-6(a), IA-5(4), PR.AC-1, PR.AC-6, PR.AC-7, FMT_SMF_EXT.1, Req-8.2.3, 8.3.6, 8.3.9, SRG-OS-000071-GPOS-00039 | |
|
Rule
Ensure PAM Enforces Password Requirements - Minimum Different Characters
[ref] | The pam_pwquality module's difok parameter sets the number of characters
in a password that must not be present in and old password during a password change.
Modify the difok setting in /etc/security/pwquality.conf
to equal 4 to require differing characters
when changing passwords. | | Rationale: | Use of a complex password helps to increase the time and resources
required to compromise the password. Password complexity, or strength,
is a measure of the effectiveness of a password in resisting attempts
at guessing and brute–force attacks.
Password complexity is one factor of several that determines how long
it takes to crack a password. The more complex the password, the
greater the number of possible combinations that need to be tested
before the password is compromised.
Requiring a minimum number of different characters during password changes ensures that
newly changed passwords should not resemble previously compromised ones.
Note that passwords which are changed on compromised systems will still be compromised, however. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_pam_difok | | Identifiers and References | References:
1, 12, 15, 16, 5, 5.6.2.1.1, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, CCI-000195, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(c), IA-5(1)(b), CM-6(a), IA-5(4), PR.AC-1, PR.AC-6, PR.AC-7, SRG-OS-000072-GPOS-00040 | |
|
Rule
Ensure PAM Enforces Password Requirements - Minimum Lowercase Characters
[ref] | The pam_pwquality module's lcredit parameter controls requirements for
usage of lowercase letters in a password. When set to a negative number, any password will be required to
contain that many lowercase characters. When set to a positive number, pam_pwquality will grant +1 additional
length credit for each lowercase character. Modify the lcredit setting in
/etc/security/pwquality.conf to require the use of a lowercase character in passwords. | | Rationale: | Use of a complex password helps to increase the time and resources required
to compromise the password. Password complexity, or strength, is a measure of
the effectiveness of a password in resisting attempts at guessing and brute-force
attacks.
Password complexity is one factor of several that determines how long it takes
to crack a password. The more complex the password, the greater the number of
possble combinations that need to be tested before the password is compromised.
Requiring a minimum number of lowercase characters makes password guessing attacks
more difficult by ensuring a larger search space. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_pam_lcredit | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, 5, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, CCI-000193, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(c), IA-5(1)(a), CM-6(a), IA-5(4), PR.AC-1, PR.AC-6, PR.AC-7, FMT_SMF_EXT.1, Req-8.2.3, 8.3.6, 8.3.9, SRG-OS-000070-GPOS-00038 | |
|
Rule
Ensure PAM Enforces Password Requirements - Maximum Consecutive Repeating Characters from Same Character Class
[ref] | The pam_pwquality module's maxclassrepeat parameter controls requirements for
consecutive repeating characters from the same character class. When set to a positive number, it will reject passwords
which contain more than that number of consecutive characters from the same character class. Modify the
maxclassrepeat setting in /etc/security/pwquality.conf to equal 4
to prevent a run of ( 4 + 1) or more identical characters. | | Rationale: | Use of a complex password helps to increase the time and resources required to compromise the password.
Password complexity, or strength, is a measure of the effectiveness of a password in resisting
attempts at guessing and brute-force attacks.
Password complexity is one factor of several that determines how long it takes to crack a password. The
more complex a password, the greater the number of possible combinations that need to be tested before the
password is compromised. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_pam_maxclassrepeat | | Identifiers and References | References:
1, 12, 15, 16, 5, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, CCI-000195, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(c), IA-5(1)(a), CM-6(a), IA-5(4), PR.AC-1, PR.AC-6, PR.AC-7, SRG-OS-000072-GPOS-00040 | |
|
Rule
Set Password Maximum Consecutive Repeating Characters
[ref] | The pam_pwquality module's maxrepeat parameter controls requirements for
consecutive repeating characters. When set to a positive number, it will reject passwords
which contain more than that number of consecutive characters. Modify the maxrepeat setting
in /etc/security/pwquality.conf to equal 3 to prevent a
run of ( 3 + 1) or more identical characters. | | Rationale: | Use of a complex password helps to increase the time and resources required to compromise the password.
Password complexity, or strength, is a measure of the effectiveness of a password in resisting attempts at
guessing and brute-force attacks.
Password complexity is one factor of several that determines how long it takes to crack a password. The more
complex the password, the greater the number of possible combinations that need to be tested before the
password is compromised.
Passwords with excessive repeating characters may be more vulnerable to password-guessing attacks. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_pam_maxrepeat | | Identifiers and References | References:
1, 12, 15, 16, 5, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, CCI-000195, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(c), CM-6(a), IA-5(4), PR.AC-1, PR.AC-6, PR.AC-7, SRG-OS-000072-GPOS-00040 | |
|
Rule
Ensure PAM Enforces Password Requirements - Minimum Length
[ref] | The pam_pwquality module's minlen parameter controls requirements for
minimum characters required in a password. Add minlen=12
after pam_pwquality to set minimum password length requirements. | | Rationale: | The shorter the password, the lower the number of possible combinations
that need to be tested before the password is compromised.
Password complexity, or strength, is a measure of the effectiveness of a
password in resisting attempts at guessing and brute-force attacks.
Password length is one factor of several that helps to determine strength
and how long it takes to crack a password. Use of more characters in a password
helps to exponentially increase the time and/or resources required to
compromise the password. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_pam_minlen | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, 5, 5.6.2.1.1, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, CCI-000205, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(c), IA-5(1)(a), CM-6(a), IA-5(4), PR.AC-1, PR.AC-6, PR.AC-7, FMT_SMF_EXT.1, Req-8.2.3, 8.3.6, 8.3.9, SRG-OS-000078-GPOS-00046 | |
|
Rule
Ensure PAM Enforces Password Requirements - Minimum Special Characters
[ref] | The pam_pwquality module's ocredit= parameter controls requirements for
usage of special (or "other") characters in a password. When set to a negative number,
any password will be required to contain that many special characters.
When set to a positive number, pam_pwquality will grant +1
additional length credit for each special character. Modify the ocredit setting
in /etc/security/pwquality.conf to equal -1
to require use of a special character in passwords. | | Rationale: | Use of a complex password helps to increase the time and resources required
to compromise the password. Password complexity, or strength, is a measure of
the effectiveness of a password in resisting attempts at guessing and brute-force
attacks.
Password complexity is one factor of several that determines how long it takes
to crack a password. The more complex the password, the greater the number of
possible combinations that need to be tested before the password is compromised.
Requiring a minimum number of special characters makes password guessing attacks
more difficult by ensuring a larger search space. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_pam_ocredit | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, 5, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, CCI-001619, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(c), IA-5(1)(a), CM-6(a), IA-5(4), PR.AC-1, PR.AC-6, PR.AC-7, FMT_SMF_EXT.1, SRG-OS-000266-GPOS-00101 | |
|
Rule
Ensure PAM Enforces Password Requirements - Minimum Uppercase Characters
[ref] | The pam_pwquality module's ucredit= parameter controls requirements for
usage of uppercase letters in a password. When set to a negative number, any password will be required to
contain that many uppercase characters. When set to a positive number, pam_pwquality will grant +1 additional
length credit for each uppercase character. Modify the ucredit setting in
/etc/security/pwquality.conf to require the use of an uppercase character in passwords. | | Rationale: | Use of a complex password helps to increase the time and resources required to compromise the password.
Password complexity, or strength, is a measure of the effectiveness of a password in resisting attempts
at guessing and brute-force attacks.
Password complexity is one factor of several that determines how long it takes to crack a password. The more
complex the password, the greater the number of possible combinations that need to be tested before
the password is compromised. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_pam_ucredit | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, 5, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, CCI-000192, CCI-000193, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(c), IA-5(1)(a), CM-6(a), IA-5(4), PR.AC-1, PR.AC-6, PR.AC-7, FMT_SMF_EXT.1, Req-8.2.3, 8.3.6, 8.3.9, SRG-OS-000069-GPOS-00037, SRG-OS-000070-GPOS-00038 | |
|
| Group
Protect Physical Console Access
Group contains 2 groups and 10 rules |
[ref]
It is impossible to fully protect a system from an
attacker with physical access, so securing the space in which the
system is located should be considered a necessary step. However,
there are some steps which, if taken, make it more difficult for an
attacker to quickly or undetectably modify a system from its
console. |
| Group
Configure Screen Locking
Group contains 1 group and 5 rules |
[ref]
When a user must temporarily leave an account
logged-in, screen locking should be employed to prevent passersby
from abusing the account. User education and training is
particularly important for screen locking to be effective, and policies
can be implemented to reinforce this.
Automatic screen locking is only meant as a safeguard for
those cases where a user forgot to lock the screen. |
| Group
Configure Console Screen Locking
Group contains 5 rules |
[ref]
A console screen locking mechanism is a temporary action taken when a user
stops work and moves away from the immediate physical vicinity of the
information system but does not logout because of the temporary nature of
the absence. Rather than relying on the user to manually lock their
operation system session prior to vacating the vicinity, operating systems
need to be able to identify when a user's session has idled and take action
to initiate the session lock. |
Rule
Install the tmux Package
[ref] | To enable console screen locking, install the tmux package.
A session lock is a temporary action taken when a user stops work and moves away from the immediate physical vicinity of the information system but does not want to log out because of the temporary nature of the absence.
The session lock is implemented at the point where session activity can be determined.
Rather than be forced to wait for a period of time to expire before the user session can be locked, Oracle Linux 9 needs to provide users with the ability to manually invoke a session lock so users can secure their session if it is necessary to temporarily vacate the immediate physical vicinity.
Instruct users to begin new terminal sessions with the following command:
$ tmux
The console can now be locked with the following key combination:
ctrl+b :lock-session | | Rationale: | A session time-out lock is a temporary action taken when a user stops work and moves away from the immediate
physical vicinity of the information system but does not logout because of the temporary nature of the absence.
Rather than relying on the user to manually lock their operation system session prior to vacating the vicinity,
operating systems need to be able to identify when a user's session has idled and take action to initiate the
session lock.
The tmux package allows for a session lock to be implemented and configured. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_package_tmux_installed | | Identifiers and References | References:
1, 12, 15, 16, DSS05.04, DSS05.10, DSS06.10, 3.1.10, CCI-000058, CCI-000056, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, SR 1.1, SR 1.10, SR 1.2, SR 1.5, SR 1.7, SR 1.8, SR 1.9, A.18.1.4, A.9.2.1, A.9.2.4, A.9.3.1, A.9.4.2, A.9.4.3, CM-6(a), PR.AC-7, FMT_SMF_EXT.1, FMT_MOF_EXT.1, FTA_SSL.1, SRG-OS-000030-GPOS-00011, SRG-OS-000028-GPOS-00009 | |
|
Rule
Support session locking with tmux
[ref] | The tmux terminal multiplexer is used to implement
automatic session locking. It should be started from
/etc/bashrc or drop-in files within /etc/profile.d/. | | Rationale: | Unlike bash itself, the tmux terminal multiplexer
provides a mechanism to lock sessions after period of inactivity.
A session lock is a temporary action taken when a user stops work and moves away from the
immediate physical vicinity of the information system but does not want to
log out because of the temporary nature of the absence. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_configure_bashrc_exec_tmux | | Identifiers and References | References:
CCI-000056, CCI-000058, FMT_SMF_EXT.1, FMT_MOF_EXT.1, FTA_SSL.1, SRG-OS-000031-GPOS-00012, SRG-OS-000028-GPOS-00009, SRG-OS-000030-GPOS-00011 | |
|
Rule
Configure tmux to lock session after inactivity
[ref] | To enable console screen locking in tmux terminal multiplexer
after a period of inactivity,
the lock-after-time option has to be set to a value greater than 0 and less than
or equal to 900 in /etc/tmux.conf. | | Rationale: | Locking the session after a period of inactivity limits the
potential exposure if the session is left unattended. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_configure_tmux_lock_after_time | | Identifiers and References | References:
CCI-000057, CCI-000060, FMT_SMF_EXT.1, FMT_MOF_EXT.1, FTA_SSL.1, SRG-OS-000029-GPOS-00010, SRG-OS-000031-GPOS-00012 | |
|
Rule
Configure the tmux Lock Command
[ref] | To enable console screen locking in tmux terminal multiplexer,
the vlock command must be configured to be used as a locking
mechanism.
Add the following line to /etc/tmux.conf:
set -g lock-command vlock .
The console can now be locked with the following key combination:
ctrl+b :lock-session | | Rationale: | The tmux package allows for a session lock to be implemented and configured.
However, the session lock is implemented by an external command. The tmux
default configuration does not contain an effective session lock. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_configure_tmux_lock_command | | Identifiers and References | References:
CCI-000056, CCI-000058, AC-11(a), AC-11(b), CM-6(a), FMT_SMF_EXT.1, FMT_MOF_EXT.1, FTA_SSL.1, SRG-OS-000028-GPOS-00009, SRG-OS-000030-GPOS-00011 | |
|
|
Rule
Disable debug-shell SystemD Service
[ref] | SystemD's debug-shell service is intended to
diagnose SystemD related boot issues with various systemctl
commands. Once enabled and following a system reboot, the root shell
will be available on tty9 which is access by pressing
CTRL-ALT-F9. The debug-shell service should only be used
for SystemD related issues and should otherwise be disabled.
By default, the debug-shell SystemD service is already disabled.
The debug-shell service can be disabled with the following command:
$ sudo systemctl mask --now debug-shell.service | | Rationale: | This prevents attackers with physical access from trivially bypassing security
on the machine through valid troubleshooting configurations and gaining root
access when the system is rebooted. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_service_debug-shell_disabled | | Identifiers and References | References:
3.4.5, CCI-000366, 164.308(a)(1)(ii)(B), 164.308(a)(7)(i), 164.308(a)(7)(ii)(A), 164.310(a)(1), 164.310(a)(2)(i), 164.310(a)(2)(ii), 164.310(a)(2)(iii), 164.310(b), 164.310(c), 164.310(d)(1), 164.310(d)(2)(iii), CM-6, FIA_UAU.1, SRG-OS-000324-GPOS-00125, SRG-OS-000480-GPOS-00227 | |
|
Rule
Disable Ctrl-Alt-Del Burst Action
[ref] | By default, SystemD will reboot the system if the Ctrl-Alt-Del
key sequence is pressed Ctrl-Alt-Delete more than 7 times in 2 seconds.
To configure the system to ignore the CtrlAltDelBurstAction
setting, add or modify the following to /etc/systemd/system.conf:
CtrlAltDelBurstAction=none Warning:
Disabling the Ctrl-Alt-Del key sequence
in /etc/init/control-alt-delete.conf DOES NOT disable the Ctrl-Alt-Del
key sequence if running in runlevel 6 (e.g. in GNOME, KDE, etc.)! The
Ctrl-Alt-Del key sequence will only be disabled if running in
the non-graphical runlevel 3. | | Rationale: | A locally logged-in user who presses Ctrl-Alt-Del, when at the console,
can reboot the system. If accidentally pressed, as could happen in
the case of mixed OS environment, this can create the risk of short-term
loss of availability of systems due to unintentional reboot. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_disable_ctrlaltdel_burstaction | | Identifiers and References | References:
12, 13, 14, 15, 16, 18, 3, 5, APO01.06, DSS05.04, DSS05.07, DSS06.02, 3.4.5, CCI-000366, 164.308(a)(1)(ii)(B), 164.308(a)(7)(i), 164.308(a)(7)(ii)(A), 164.310(a)(1), 164.310(a)(2)(i), 164.310(a)(2)(ii), 164.310(a)(2)(iii), 164.310(b), 164.310(c), 164.310(d)(1), 164.310(d)(2)(iii), 4.3.3.7.3, SR 2.1, SR 5.2, A.10.1.1, A.11.1.4, A.11.1.5, A.11.2.1, A.13.1.1, A.13.1.3, A.13.2.1, A.13.2.3, A.13.2.4, A.14.1.2, A.14.1.3, A.6.1.2, A.7.1.1, A.7.1.2, A.7.3.1, A.8.2.2, A.8.2.3, A.9.1.1, A.9.1.2, A.9.2.3, A.9.4.1, A.9.4.4, A.9.4.5, CIP-003-8 R5.1.1, CIP-003-8 R5.3, CIP-004-6 R2.3, CIP-007-3 R2.1, CIP-007-3 R2.2, CIP-007-3 R2.3, CIP-007-3 R5.1, CIP-007-3 R5.1.1, CIP-007-3 R5.1.2, CM-6(a), AC-6(1), CM-6(a), PR.AC-4, PR.DS-5, FAU_GEN.1.2, SRG-OS-000324-GPOS-00125, SRG-OS-000480-GPOS-00227 | |
|
Rule
Disable Ctrl-Alt-Del Reboot Activation
[ref] | By default, SystemD will reboot the system if the Ctrl-Alt-Del
key sequence is pressed.
To configure the system to ignore the Ctrl-Alt-Del key sequence from the
command line instead of rebooting the system, do either of the following:
ln -sf /dev/null /etc/systemd/system/ctrl-alt-del.target
or
systemctl mask ctrl-alt-del.target
Do not simply delete the /usr/lib/systemd/system/ctrl-alt-del.service file,
as this file may be restored during future system updates. | | Rationale: | A locally logged-in user who presses Ctrl-Alt-Del, when at the console,
can reboot the system. If accidentally pressed, as could happen in
the case of mixed OS environment, this can create the risk of short-term
loss of availability of systems due to unintentional reboot. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_disable_ctrlaltdel_reboot | | Identifiers and References | References:
12, 13, 14, 15, 16, 18, 3, 5, APO01.06, DSS05.04, DSS05.07, DSS06.02, 3.4.5, CCI-000366, 164.308(a)(1)(ii)(B), 164.308(a)(7)(i), 164.308(a)(7)(ii)(A), 164.310(a)(1), 164.310(a)(2)(i), 164.310(a)(2)(ii), 164.310(a)(2)(iii), 164.310(b), 164.310(c), 164.310(d)(1), 164.310(d)(2)(iii), 4.3.3.7.3, SR 2.1, SR 5.2, A.10.1.1, A.11.1.4, A.11.1.5, A.11.2.1, A.13.1.1, A.13.1.3, A.13.2.1, A.13.2.3, A.13.2.4, A.14.1.2, A.14.1.3, A.6.1.2, A.7.1.1, A.7.1.2, A.7.3.1, A.8.2.2, A.8.2.3, A.9.1.1, A.9.1.2, A.9.2.3, A.9.4.1, A.9.4.4, A.9.4.5, CIP-003-8 R5.1.1, CIP-003-8 R5.3, CIP-004-6 R2.3, CIP-007-3 R2.1, CIP-007-3 R2.2, CIP-007-3 R2.3, CIP-007-3 R5.1, CIP-007-3 R5.1.1, CIP-007-3 R5.1.2, CM-6(a), AC-6(1), PR.AC-4, PR.DS-5, FAU_GEN.1.2, SRG-OS-000324-GPOS-00125, SRG-OS-000480-GPOS-00227 | |
|
Rule
Verify that Interactive Boot is Disabled
[ref] | Oracle Linux 9 systems support an "interactive boot" option that can
be used to prevent services from being started. On a Oracle Linux 9
system, interactive boot can be enabled by providing a 1,
yes, true, or on value to the
systemd.confirm_spawn kernel argument in /etc/default/grub.
Remove any instance of systemd.confirm_spawn=(1|yes|true|on) from
the kernel arguments in that file to disable interactive boot.
Recovery booting must also be disabled. Confirm that
GRUB_DISABLE_RECOVERY=true is set in /etc/default/grub.
It is also required to change the runtime configuration, run:
/sbin/grubby --update-kernel=ALL --remove-args="systemd.confirm_spawn"
grub2-mkconfig -o /boot/grub2/grub.cfg | | Rationale: | Using interactive or recovery boot, the console user could disable auditing, firewalls,
or other services, weakening system security. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_grub2_disable_interactive_boot | | Identifiers and References | References:
11, 12, 14, 15, 16, 18, 3, 5, DSS05.02, DSS05.04, DSS05.05, DSS05.07, DSS06.03, DSS06.06, 3.1.2, 3.4.5, CCI-000213, 164.308(a)(1)(ii)(B), 164.308(a)(7)(i), 164.308(a)(7)(ii)(A), 164.310(a)(1), 164.310(a)(2)(i), 164.310(a)(2)(ii), 164.310(a)(2)(iii), 164.310(b), 164.310(c), 164.310(d)(1), 164.310(d)(2)(iii), 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.5.3, 4.3.3.5.4, 4.3.3.5.5, 4.3.3.5.6, 4.3.3.5.7, 4.3.3.5.8, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.1, 4.3.3.7.2, 4.3.3.7.3, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.11, SR 1.12, SR 1.13, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.6, SR 1.7, SR 1.8, SR 1.9, SR 2.1, SR 2.2, SR 2.3, SR 2.4, SR 2.5, SR 2.6, SR 2.7, A.6.1.2, A.7.1.1, A.9.1.2, A.9.2.1, A.9.2.3, A.9.4.1, A.9.4.4, A.9.4.5, SC-2(1), CM-6(a), PR.AC-4, PR.AC-6, PR.PT-3, FIA_UAU.1, SRG-OS-000480-GPOS-00227 | |
|
Rule
Require Authentication for Single User Mode
[ref] | Single-user mode is intended as a system recovery
method, providing a single user root access to the system by
providing a boot option at startup.
By default, single-user mode is protected by requiring a password and is set
in /usr/lib/systemd/system/rescue.service. | | Rationale: | This prevents attackers with physical access from trivially bypassing security
on the machine and gaining root access. Such accesses are further prevented
by configuring the bootloader password. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_require_singleuser_auth | | Identifiers and References | References:
1, 11, 12, 14, 15, 16, 18, 3, 5, DSS05.02, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.06, DSS06.10, 3.1.1, 3.4.5, CCI-000213, 164.308(a)(1)(ii)(B), 164.308(a)(7)(i), 164.308(a)(7)(ii)(A), 164.310(a)(1), 164.310(a)(2)(i), 164.310(a)(2)(ii), 164.310(a)(2)(iii), 164.310(b), 164.310(c), 164.310(d)(1), 164.310(d)(2)(iii), 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.5.3, 4.3.3.5.4, 4.3.3.5.5, 4.3.3.5.6, 4.3.3.5.7, 4.3.3.5.8, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.1, 4.3.3.7.2, 4.3.3.7.3, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.11, SR 1.12, SR 1.13, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.6, SR 1.7, SR 1.8, SR 1.9, SR 2.1, SR 2.2, SR 2.3, SR 2.4, SR 2.5, SR 2.6, SR 2.7, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.6.1.2, A.7.1.1, A.9.1.2, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.1, A.9.4.2, A.9.4.3, A.9.4.4, A.9.4.5, CIP-003-8 R5.1.1, CIP-003-8 R5.3, CIP-004-6 R2.2.3, CIP-004-6 R2.3, CIP-007-3 R5.1, CIP-007-3 R5.1.2, CIP-007-3 R5.2, CIP-007-3 R5.3.1, CIP-007-3 R5.3.2, CIP-007-3 R5.3.3, IA-2, AC-3, CM-6(a), PR.AC-1, PR.AC-4, PR.AC-6, PR.AC-7, PR.PT-3, FIA_UAU.1, SRG-OS-000080-GPOS-00048 | |
|
| Group
Protect Accounts by Restricting Password-Based Login
Group contains 3 groups and 4 rules |
[ref]
Conventionally, Unix shell accounts are accessed by
providing a username and password to a login program, which tests
these values for correctness using the /etc/passwd and
/etc/shadow files. Password-based login is vulnerable to
guessing of weak passwords, and to sniffing and man-in-the-middle
attacks against passwords entered over a network or at an insecure
console. Therefore, mechanisms for accessing accounts by entering
usernames and passwords should be restricted to those which are
operationally necessary. |
| Group
Set Password Expiration Parameters
Group contains 1 rule |
[ref]
The file /etc/login.defs controls several
password-related settings. Programs such as passwd,
su, and
login consult /etc/login.defs to determine
behavior with regard to password aging, expiration warnings,
and length. See the man page login.defs(5) for more information.
Users should be forced to change their passwords, in order to
decrease the utility of compromised passwords. However, the need to
change passwords often should be balanced against the risk that
users will reuse or write down passwords if forced to change them
too often. Forcing password changes every 90-360 days, depending on
the environment, is recommended. Set the appropriate value as
PASS_MAX_DAYS and apply it to existing accounts with the
-M flag.
The PASS_MIN_DAYS ( -m) setting prevents password
changes for 7 days after the first change, to discourage password
cycling. If you use this setting, train users to contact an administrator
for an emergency password change in case a new password becomes
compromised. The PASS_WARN_AGE ( -W) setting gives
users 7 days of warnings at login time that their passwords are about to expire.
For example, for each existing human user USER, expiration parameters
could be adjusted to a 180 day maximum password age, 7 day minimum password
age, and 7 day warning period with the following command:
$ sudo chage -M 180 -m 7 -W 7 USER |
Rule
Set Password Minimum Length in login.defs
[ref] | To specify password length requirements for new accounts, edit the file
/etc/login.defs and add or correct the following line:
PASS_MIN_LEN 12
The DoD requirement is 15.
The FISMA requirement is 12.
The profile requirement is
12.
If a program consults /etc/login.defs and also another PAM module
(such as pam_pwquality) during a password change operation, then
the most restrictive must be satisfied. See PAM section for more
information about enforcing password quality requirements. | | Rationale: | Requiring a minimum password length makes password
cracking attacks more difficult by ensuring a larger
search space. However, any security benefit from an onerous requirement
must be carefully weighed against usability problems, support costs, or counterproductive
behavior that may result. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_password_minlen_login_defs | | Identifiers and References | References:
BP28(R18), 1, 12, 15, 16, 5, 5.6.2.1, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, 3.5.7, CCI-000205, 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, 0421, 0422, 0431, 0974, 1173, 1401, 1504, 1505, 1546, 1557, 1558, 1559, 1560, 1561, A.18.1.4, A.7.1.1, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.2, A.9.4.3, IA-5(f), IA-5(1)(a), CM-6(a), PR.AC-1, PR.AC-6, PR.AC-7, SRG-OS-000078-GPOS-00046 | |
|
| Group
Verify Proper Storage and Existence of Password
Hashes
Group contains 1 rule |
[ref]
By default, password hashes for local accounts are stored
in the second field (colon-separated) in
/etc/shadow. This file should be readable only by
processes running with root credentials, preventing users from
casually accessing others' password hashes and attempting
to crack them.
However, it remains possible to misconfigure the system
and store password hashes
in world-readable files such as /etc/passwd, or
to even store passwords themselves in plaintext on the system.
Using system-provided tools for password change/creation
should allow administrators to avoid such misconfiguration. |
Rule
Prevent Login to Accounts With Empty Password
[ref] | If an account is configured for password authentication
but does not have an assigned password, it may be possible to log
into the account without authentication. Remove any instances of the
nullok in
/etc/pam.d/system-auth and
/etc/pam.d/password-auth
to prevent logins with empty passwords. Warning:
If the system relies on authselect tool to manage PAM settings, the remediation
will also use authselect tool. However, if any manual modification was made in
PAM files, the authselect integrity check will fail and the remediation will be
aborted in order to preserve intentional changes. In this case, an informative message will
be shown in the remediation report.
Note that this rule is not applicable for systems running within a
container. Having user with empty password within a container is not
considered a risk, because it should not be possible to directly login into
a container anyway. | | Rationale: | If an account has an empty password, anyone could log in and
run commands with the privileges of that account. Accounts with
empty passwords should never be used in operational environments. | | Severity: | high | | Rule ID: | xccdf_org.ssgproject.content_rule_no_empty_passwords | | Identifiers and References | References:
1, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2, APO01.06, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.02, DSS06.03, DSS06.10, 3.1.1, 3.1.5, CCI-000366, 164.308(a)(1)(ii)(B), 164.308(a)(7)(i), 164.308(a)(7)(ii)(A), 164.310(a)(1), 164.310(a)(2)(i), 164.310(a)(2)(ii), 164.310(a)(2)(iii), 164.310(b), 164.310(c), 164.310(d)(1), 164.310(d)(2)(iii), 4.3.3.2.2, 4.3.3.5.1, 4.3.3.5.2, 4.3.3.6.1, 4.3.3.6.2, 4.3.3.6.3, 4.3.3.6.4, 4.3.3.6.5, 4.3.3.6.6, 4.3.3.6.7, 4.3.3.6.8, 4.3.3.6.9, 4.3.3.7.2, 4.3.3.7.3, 4.3.3.7.4, SR 1.1, SR 1.10, SR 1.2, SR 1.3, SR 1.4, SR 1.5, SR 1.7, SR 1.8, SR 1.9, SR 2.1, SR 5.2, A.10.1.1, A.11.1.4, A.11.1.5, A.11.2.1, A.13.1.1, A.13.1.3, A.13.2.1, A.13.2.3, A.13.2.4, A.14.1.2, A.14.1.3, A.18.1.4, A.6.1.2, A.7.1.1, A.7.1.2, A.7.3.1, A.8.2.2, A.8.2.3, A.9.1.1, A.9.1.2, A.9.2.1, A.9.2.2, A.9.2.3, A.9.2.4, A.9.2.6, A.9.3.1, A.9.4.1, A.9.4.2, A.9.4.3, A.9.4.4, A.9.4.5, IA-5(1)(a), IA-5(c), CM-6(a), PR.AC-1, PR.AC-4, PR.AC-6, PR.AC-7, PR.DS-5, FIA_UAU.1, Req-8.2.3, 8.3.6, 8.3.9, SRG-OS-000480-GPOS-00227 | |
|
| Group
Restrict Root Logins
Group contains 2 rules |
[ref]
Direct root logins should be allowed only for emergency use.
In normal situations, the administrator should access the system
via a unique unprivileged account, and then use su or sudo to execute
privileged commands. Discouraging administrators from accessing the
root account directly ensures an audit trail in organizations with
multiple administrators. Locking down the channels through which
root can connect directly also reduces opportunities for
password-guessing against the root account. The login program
uses the file /etc/securetty to determine which interfaces
should allow root logins.
The virtual devices /dev/console
and /dev/tty* represent the system consoles (accessible via
the Ctrl-Alt-F1 through Ctrl-Alt-F6 keyboard sequences on a default
installation). The default securetty file also contains /dev/vc/*.
These are likely to be deprecated in most environments, but may be retained
for compatibility. Root should also be prohibited from connecting
via network protocols. Other sections of this document
include guidance describing how to prevent root from logging in via SSH. |
Rule
Restrict Virtual Console Root Logins
[ref] | To restrict root logins through the (deprecated) virtual console devices,
ensure lines of this form do not appear in /etc/securetty:
vc/1
vc/2
vc/3
vc/4 | | Rationale: | Preventing direct root login to virtual console devices
helps ensure accountability for actions taken on the system
using the root account. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_securetty_root_login_console_only | | Identifiers and References | References:
12, 13, 14, 15, 16, 18, 3, 5, APO01.06, DSS05.04, DSS05.07, DSS06.02, 3.1.1, 3.1.5, CCI-000770, 164.308(a)(1)(ii)(B), 164.308(a)(7)(i), 164.308(a)(7)(ii)(A), 164.310(a)(1), 164.310(a)(2)(i), 164.310(a)(2)(ii), 164.310(a)(2)(iii), 164.310(b), 164.310(c), 164.310(d)(1), 164.310(d)(2)(iii), 4.3.3.7.3, SR 2.1, SR 5.2, A.10.1.1, A.11.1.4, A.11.1.5, A.11.2.1, A.13.1.1, A.13.1.3, A.13.2.1, A.13.2.3, A.13.2.4, A.14.1.2, A.14.1.3, A.6.1.2, A.7.1.1, A.7.1.2, A.7.3.1, A.8.2.2, A.8.2.3, A.9.1.1, A.9.1.2, A.9.2.3, A.9.4.1, A.9.4.4, A.9.4.5, CIP-003-8 R5.1.1, CIP-003-8 R5.3, CIP-004-6 R2.3, CIP-007-3 R2.1, CIP-007-3 R2.2, CIP-007-3 R2.3, CIP-007-3 R5.1, CIP-007-3 R5.1.1, CIP-007-3 R5.1.2, AC-6, CM-6(a), PR.AC-4, PR.DS-5, 8.6.1, SRG-OS-000324-GPOS-00125 | |
|
Rule
Enforce usage of pam_wheel for su authentication
[ref] | To ensure that only users who are members of the wheel group can
run commands with altered privileges through the su command, make
sure that the following line exists in the file /etc/pam.d/su:
auth required pam_wheel.so use_uid Warning:
Members of "wheel" or GID 0 groups are checked by default if the group option is not set
for pam_wheel.so module. Therefore, members of these groups should be manually checked or
a different group should be informed according to the site policy. | | Rationale: | The su program allows to run commands with a substitute user and
group ID. It is commonly used to run commands as the root user. Limiting
access to such command is considered a good security practice. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_use_pam_wheel_for_su | | Identifiers and References | References:
FMT_SMF_EXT.1.1, 8.6.1, SRG-OS-000373-GPOS-00156, SRG-OS-000312-GPOS-00123 | |
|
| Group
Secure Session Configuration Files for Login Accounts
Group contains 1 group and 4 rules |
[ref]
When a user logs into a Unix account, the system
configures the user's session by reading a number of files. Many of
these files are located in the user's home directory, and may have
weak permissions as a result of user error or misconfiguration. If
an attacker can modify or even read certain types of account
configuration information, they can often gain full access to the
affected user's account. Therefore, it is important to test and
correct configuration file permissions for interactive accounts,
particularly those of privileged users such as root or system
administrators. |
| Group
Ensure that Users Have Sensible Umask Values
Group contains 3 rules |
[ref]
The umask setting controls the default permissions
for the creation of new files.
With a default umask setting of 077, files and directories
created by users will not be readable by any other user on the
system. Users who wish to make specific files group- or
world-readable can accomplish this by using the chmod command.
Additionally, users can make all their files readable to their
group by default by setting a umask of 027 in their shell
configuration files. If default per-user groups exist (that is, if
every user has a default group whose name is the same as that
user's username and whose only member is the user), then it may
even be safe for users to select a umask of 007, making it very
easy to intentionally share files with groups of which the user is
a member.
|
Rule
Ensure the Default Bash Umask is Set Correctly
[ref] | To ensure the default umask for users of the Bash shell is set properly,
add or correct the umask setting in /etc/bashrc to read
as follows:
umask 027 | | Rationale: | The umask value influences the permissions assigned to files when they are created.
A misconfigured umask value could result in files with excessive permissions that can be read or
written to by unauthorized users. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_umask_etc_bashrc | | Identifiers and References | References:
BP28(R35), 18, APO13.01, BAI03.01, BAI03.02, BAI03.03, CCI-000366, 4.3.4.3.3, A.14.1.1, A.14.2.1, A.14.2.5, A.6.1.5, CIP-003-8 R5.1.1, CIP-003-8 R5.3, CIP-004-6 R2.3, CIP-007-3 R2.1, CIP-007-3 R2.2, CIP-007-3 R2.3, CIP-007-3 R5.1, CIP-007-3 R5.1.1, CIP-007-3 R5.1.2, AC-6(1), CM-6(a), PR.IP-2, 8.6.1, SRG-OS-000480-GPOS-00228, SRG-OS-000480-GPOS-00227 | |
|
Rule
Ensure the Default C Shell Umask is Set Correctly
[ref] | To ensure the default umask for users of the C shell is set properly,
add or correct the umask setting in /etc/csh.cshrc to read as follows:
umask 027 | | Rationale: | The umask value influences the permissions assigned to files when they are created.
A misconfigured umask value could result in files with excessive permissions that can be read or
written to by unauthorized users. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_umask_etc_csh_cshrc | | Identifiers and References | References:
18, APO13.01, BAI03.01, BAI03.02, BAI03.03, CCI-000366, 4.3.4.3.3, A.14.1.1, A.14.2.1, A.14.2.5, A.6.1.5, CIP-003-8 R5.1.1, CIP-003-8 R5.3, CIP-004-6 R2.3, CIP-007-3 R2.1, CIP-007-3 R2.2, CIP-007-3 R2.3, CIP-007-3 R5.1, CIP-007-3 R5.1.1, CIP-007-3 R5.1.2, AC-6(1), CM-6(a), PR.IP-2, SRG-OS-000480-GPOS-00228, SRG-OS-000480-GPOS-00227 | |
|
Rule
Ensure the Default Umask is Set Correctly in /etc/profile
[ref] | To ensure the default umask controlled by /etc/profile is set properly,
add or correct the umask setting in /etc/profile to read as follows:
umask 027
Note that /etc/profile also reads scrips within /etc/profile.d directory.
These scripts are also valid files to set umask value. Therefore, they should also be
considered during the check and properly remediated, if necessary. | | Rationale: | The umask value influences the permissions assigned to files when they are created.
A misconfigured umask value could result in files with excessive permissions that can be read or
written to by unauthorized users. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_umask_etc_profile | | Identifiers and References | References:
BP28(R35), 18, APO13.01, BAI03.01, BAI03.02, BAI03.03, CCI-000366, 4.3.4.3.3, A.14.1.1, A.14.2.1, A.14.2.5, A.6.1.5, CIP-003-8 R5.1.1, CIP-003-8 R5.3, CIP-004-6 R2.3, CIP-007-3 R2.1, CIP-007-3 R2.2, CIP-007-3 R2.3, CIP-007-3 R5.1, CIP-007-3 R5.1.1, CIP-007-3 R5.1.2, AC-6(1), CM-6(a), PR.IP-2, 8.6.1, SRG-OS-000480-GPOS-00228, SRG-OS-000480-GPOS-00227 | |
|
Rule
Limit the Number of Concurrent Login Sessions Allowed Per User
[ref] | Limiting the number of allowed users and sessions per user can limit risks related to Denial of
Service attacks. This addresses concurrent sessions for a single account and does not address
concurrent sessions by a single user via multiple accounts. To set the number of concurrent
sessions per user add the following line in /etc/security/limits.conf or
a file under /etc/security/limits.d/:
* hard maxlogins 10 | | Rationale: | Limiting simultaneous user logins can insulate the system from denial of service
problems caused by excessive logins. Automated login processes operating improperly or
maliciously may result in an exceptional number of simultaneous login sessions. | | Severity: | low | | Rule ID: | xccdf_org.ssgproject.content_rule_accounts_max_concurrent_login_sessions | | Identifiers and References | References:
14, 15, 18, 9, 5.5.2.2, DSS01.05, DSS05.02, CCI-000054, 4.3.3.4, SR 3.1, SR 3.8, A.13.1.1, A.13.1.3, A.13.2.1, A.14.1.2, A.14.1.3, CIP-007-3 R5.1, CIP-007-3 R5.1.2, AC-10, CM-6(a), PR.AC-5, SRG-OS-000027-GPOS-00008 | |
|
| Group
System Accounting with auditd
Group contains 2 groups and 25 rules |
[ref]
The audit service provides substantial capabilities
for recording system activities. By default, the service audits about
SELinux AVC denials and certain types of security-relevant events
such as system logins, account modifications, and authentication
events performed by programs such as sudo.
Under its default configuration, auditd has modest disk space
requirements, and should not noticeably impact system performance.
NOTE: The Linux Audit daemon auditd can be configured to use
the augenrules program to read audit rules files ( *.rules)
located in /etc/audit/rules.d location and compile them to create
the resulting form of the /etc/audit/audit.rules configuration file
during the daemon startup (default configuration). Alternatively, the auditd
daemon can use the auditctl utility to read audit rules from the
/etc/audit/audit.rules configuration file during daemon startup,
and load them into the kernel. The expected behavior is configured via the
appropriate ExecStartPost directive setting in the
/usr/lib/systemd/system/auditd.service configuration file.
To instruct the auditd daemon to use the augenrules program
to read audit rules (default configuration), use the following setting:
ExecStartPost=-/sbin/augenrules --load
in the /usr/lib/systemd/system/auditd.service configuration file.
In order to instruct the auditd daemon to use the auditctl
utility to read audit rules, use the following setting:
ExecStartPost=-/sbin/auditctl -R /etc/audit/audit.rules
in the /usr/lib/systemd/system/auditd.service configuration file.
Refer to [Service] section of the /usr/lib/systemd/system/auditd.service
configuration file for further details.
Government networks often have substantial auditing
requirements and auditd can be configured to meet these
requirements.
Examining some example audit records demonstrates how the Linux audit system
satisfies common requirements.
The following example from Red Hat Enterprise Linux 7 Documentation available at
https://access.redhat.com/documentation/en-us/red_hat_enterprise_linux/7/html-single/selinux_users_and_administrators_guide/index#sect-Security-Enhanced_Linux-Fixing_Problems-Raw_Audit_Messages
shows the substantial amount of information captured in a
two typical "raw" audit messages, followed by a breakdown of the most important
fields. In this example the message is SELinux-related and reports an AVC
denial (and the associated system call) that occurred when the Apache HTTP
Server attempted to access the /var/www/html/file1 file (labeled with
the samba_share_t type):
type=AVC msg=audit(1226874073.147:96): avc: denied { getattr } for pid=2465 comm="httpd"
path="/var/www/html/file1" dev=dm-0 ino=284133 scontext=unconfined_u:system_r:httpd_t:s0
tcontext=unconfined_u:object_r:samba_share_t:s0 tclass=file
type=SYSCALL msg=audit(1226874073.147:96): arch=40000003 syscall=196 success=no exit=-13
a0=b98df198 a1=bfec85dc a2=54dff4 a3=2008171 items=0 ppid=2463 pid=2465 auid=502 uid=48
gid=48 euid=48 suid=48 fsuid=48 egid=48 sgid=48 fsgid=48 tty=(none) ses=6 comm="httpd"
exe="/usr/sbin/httpd" subj=unconfined_u:system_r:httpd_t:s0 key=(null)
msg=audit(1226874073.147:96)- The number in parentheses is the unformatted time stamp (Epoch time)
for the event, which can be converted to standard time by using the
date command.
{ getattr }- The item in braces indicates the permission that was denied.
getattr
indicates the source process was trying to read the target file's status information.
This occurs before reading files. This action is denied due to the file being
accessed having the wrong label. Commonly seen permissions include getattr,
read, and write.
comm="httpd"- The executable that launched the process. The full path of the executable is
found in the
exe= section of the system call (SYSCALL) message,
which in this case, is exe="/usr/sbin/httpd".
path="/var/www/html/file1"- The path to the object (target) the process attempted to access.
scontext="unconfined_u:system_r:httpd_t:s0"- The SELinux context of the process that attempted the denied action. In
this case, it is the SELinux context of the Apache HTTP Server, which is running
in the
httpd_t domain.
tcontext="unconfined_u:object_r:samba_share_t:s0"- The SELinux context of the object (target) the process attempted to access.
In this case, it is the SELinux context of
file1. Note: the samba_share_t
type is not accessible to processes running in the httpd_t domain.
- From the system call (
SYSCALL) message, two items are of interest:
success=no: indicates whether the denial (AVC) was enforced or not.
success=no indicates the system call was not successful (SELinux denied
access). success=yes indicates the system call was successful - this can
be seen for permissive domains or unconfined domains, such as initrc_t
and kernel_t.
exe="/usr/sbin/httpd": the full path to the executable that launched
the process, which in this case, is exe="/usr/sbin/httpd".
|
| Group
Configure auditd Data Retention
Group contains 4 rules |
[ref]
The audit system writes data to /var/log/audit/audit.log. By default,
auditd rotates 5 logs by size (6MB), retaining a maximum of 30MB of
data in total, and refuses to write entries when the disk is too
full. This minimizes the risk of audit data filling its partition
and impacting other services. This also minimizes the risk of the audit
daemon temporarily disabling the system if it cannot write audit log (which
it can be configured to do).
For a busy
system or a system which is thoroughly auditing system activity, the default settings
for data retention may be
insufficient. The log file size needed will depend heavily on what types
of events are being audited. First configure auditing to log all the events of
interest. Then monitor the log size manually for awhile to determine what file
size will allow you to keep the required data for the correct time period.
Using a dedicated partition for /var/log/audit prevents the
auditd logs from disrupting system functionality if they fill, and,
more importantly, prevents other activity in /var from filling the
partition and stopping the audit trail. (The audit logs are size-limited and
therefore unlikely to grow without bound unless configured to do so.) Some
machines may have requirements that no actions occur which cannot be audited.
If this is the case, then auditd can be configured to halt the machine
if it runs out of space. Note: Since older logs are rotated,
configuring auditd this way does not prevent older logs from being
rotated away before they can be viewed.
If your system is configured to halt when logging cannot be performed, make
sure this can never happen under normal circumstances! Ensure that
/var/log/audit is on its own partition, and that this partition is
larger than the maximum amount of data auditd will retain
normally. |
Rule
Configure auditd flush priority
[ref] | The auditd service can be configured to
synchronously write audit event data to disk. Add or correct the following
line in /etc/audit/auditd.conf to ensure that audit event data is
fully synchronized with the log files on the disk:
flush = incremental_async | | Rationale: | Audit data should be synchronously written to disk to ensure
log integrity. These parameters assure that all audit event data is fully
synchronized with the log files on the disk. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_auditd_data_retention_flush | | Identifiers and References | References:
1, 12, 13, 14, 15, 16, 2, 3, 5, 6, 7, 8, 9, APO10.01, APO10.03, APO10.04, APO10.05, APO11.04, BAI03.05, DSS01.03, DSS03.05, DSS05.02, DSS05.04, DSS05.05, DSS05.07, MEA01.01, MEA01.02, MEA01.03, MEA01.04, MEA01.05, MEA02.01, 3.3.1, CCI-001576, 164.308(a)(1)(ii)(D), 164.308(a)(3)(ii)(A), 164.308(a)(5)(ii)(C), 164.312(a)(2)(i), 164.312(b), 164.312(d), 164.312(e), 4.3.2.6.7, 4.3.3.3.9, 4.3.3.5.8, 4.3.4.4.7, 4.4.2.1, 4.4.2.2, 4.4.2.4, SR 2.10, SR 2.11, SR 2.12, SR 2.8, SR 2.9, SR 6.1, SR 6.2, A.12.4.1, A.12.4.2, A.12.4.3, A.12.4.4, A.12.7.1, A.14.2.7, A.15.2.1, A.15.2.2, CIP-004-6 R2.2.3, CIP-004-6 R3.3, CIP-007-3 R5.2, CIP-007-3 R5.3.1, CIP-007-3 R5.3.2, CIP-007-3 R5.3.3, CIP-007-3 R6.5, AU-11, CM-6(a), DE.CM-1, DE.CM-3, DE.CM-7, ID.SC-4, PR.PT-1, SRG-OS-000480-GPOS-00227 | |
|
Rule
Set number of records to cause an explicit flush to audit logs
[ref] | To configure Audit daemon to issue an explicit flush to disk command
after writing 50 records, set freq to 50
in /etc/audit/auditd.conf. | | Rationale: | If option freq isn't set to 50, the flush to disk
may happen after higher number of records, increasing the danger
of audit loss. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_auditd_freq | | Identifiers and References | References:
CM-6, FAU_GEN.1, SRG-OS-000051-GPOS-00024 | |
|
Rule
Resolve information before writing to audit logs
[ref] | To configure Audit daemon to resolve all uid, gid, syscall,
architecture, and socket address information before writing the
events to disk, set log_format to ENRICHED
in /etc/audit/auditd.conf. | | Rationale: | If option log_format isn't set to ENRICHED, the
audit records will be stored in a format exactly as the kernel sends them. | | Severity: | low | | Rule ID: | xccdf_org.ssgproject.content_rule_auditd_log_format | | Identifiers and References | References:
CCI-000366, CM-6, AU-3, FAU_GEN.1.2, SRG-OS-000255-GPOS-00096, SRG-OS-000480-GPOS-00227, SRG-APP-000096-CTR-000175, SRG-APP-000097-CTR-000180, SRG-APP-000098-CTR-000185, SRG-APP-000099-CTR-000190, SRG-APP-000100-CTR-000195, SRG-APP-000100-CTR-000200, SRG-APP-000109-CTR-000215, SRG-APP-000290-CTR-000670, SRG-APP-000357-CTR-000800 | |
|
Rule
Set type of computer node name logging in audit logs
[ref] | To configure Audit daemon to use a unique identifier
as computer node name in the audit events,
set name_format to hostname
in /etc/audit/auditd.conf. Warning:
Whenever the variable var_auditd_name_format uses a multiple value option, for example
A|B|C , the first value will be used when remediating this rule. | | Rationale: | If option name_format is left at its default value of
none, audit events from different computers may be hard
to distinguish. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_auditd_name_format | | Identifiers and References | References:
CCI-001851, CM-6, AU-3, FAU_GEN.1.2, SRG-OS-000039-GPOS-00017, SRG-OS-000342-GPOS-00133, SRG-OS-000479-GPOS-00224 | |
|
| Group
System Accounting with auditd
Group contains 16 rules |
[ref]
The auditd program can perform comprehensive
monitoring of system activity. This section makes use of recommended
configuration settings for specific policies or use cases.
The rules in this section make use of rules defined in /usr/share/doc/audit-VERSION/rules. |
Rule
Configure auditing of unsuccessful file accesses
[ref] | Ensure that unsuccessful attempts to access a file are audited.
The following rules configure audit as described above:
## Unsuccessful file access (any other opens) This has to go last.
-a always,exit -F arch=b32 -S open,openat,openat2,open_by_handle_at -F exit=-EACCES -F auid>=1000 -F auid!=unset -F key=unsuccessful-access
-a always,exit -F arch=b64 -S open,openat,openat2,open_by_handle_at -F exit=-EACCES -F auid>=1000 -F auid!=unset -F key=unsuccessful-access
-a always,exit -F arch=b32 -S open,openat,openat2,open_by_handle_at -F exit=-EPERM -F auid>=1000 -F auid!=unset -F key=unsuccessful-access
-a always,exit -F arch=b64 -S open,openat,openat2,open_by_handle_at -F exit=-EPERM -F auid>=1000 -F auid!=unset -F key=unsuccessful-access
Load new Audit rules into kernel by running:
augenrules --load
Note: This rule uses a special set of Audit rules to comply with OSPP 4.2.1. You may reuse this rule in different profiles. If you decide to do so, it is recommended that you inspect contents of the file closely and make sure that they are alligned with your needs. | | Rationale: | Unsuccessful attempts to access a file might be signs of malicious activity happening within the system. Auditing of such activities helps in their monitoring and investigation. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_audit_access_failed | | Identifiers and References | References:
0582, 0584, 05885, 0586, 0846, 0957, AU-2(a), FAU_GEN.1.1.c, SRG-OS-000458-GPOS-00203, SRG-OS-000474-GPOS-00219, SRG-OS-000475-GPOS-00220, SRG-OS-000463-GPOS-00207, SRG-OS-000465-GPOS-00209, SRG-OS-000461-GPOS-00205, SRG-APP-000091-CTR-000160, SRG-APP-000492-CTR-001220, SRG-APP-000493-CTR-001225, SRG-APP-000494-CTR-001230, SRG-APP-000500-CTR-001260, SRG-APP-000507-CTR-001295 | |
|
Rule
Configure auditing of successful file accesses
[ref] | Ensure that successful attempts to access a file are audited.
The following rules configure audit as described above:
## Successful file access (any other opens) This has to go last.
## These next two are likely to result in a whole lot of events
-a always,exit -F arch=b32 -S open,openat,openat2,open_by_handle_at -F success=1 -F auid>=1000 -F auid!=unset -F key=successful-access
-a always,exit -F arch=b64 -S open,openat,openat2,open_by_handle_at -F success=1 -F auid>=1000 -F auid!=unset -F key=successful-access
Load new Audit rules into kernel by running:
augenrules --load
Note: This rule uses a special set of Audit rules to comply with OSPP 4.2.1. You may reuse this rule in different profiles. If you decide to do so, it is recommended that you inspect contents of the file closely and make sure that they are alligned with your needs. | | Rationale: | Auditing of successful attempts to access a file helps in investigation of activities performed on the system. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_audit_access_success | | Identifiers and References | References:
0582, 0584, 05885, 0586, 0846, 0957, AU-2(a), FAU_GEN.1.1.c, SRG-OS-000458-GPOS-00203, SRG-OS-000474-GPOS-00219, SRG-OS-000475-GPOS-00220, SRG-OS-000463-GPOS-00207, SRG-OS-000465-GPOS-00209, SRG-OS-000461-GPOS-00205 | |
|
Rule
Configure basic parameters of Audit system
[ref] | Perform basic configuration of Audit system.
Make sure that any previously defined rules are cleared, the auditing system is configured to handle sudden bursts of events, and in cases of failure, messages are configured to be directed to system log.
The following rules configure audit as described above:
## First rule - delete all
-D
## Increase the buffers to survive stress events.
## Make this bigger for busy systems
-b 8192
## This determine how long to wait in burst of events
--backlog_wait_time 60000
## Set failure mode to syslog
-f 1
Load new Audit rules into kernel by running:
augenrules --load Warning:
It might happen that Audit buffer configured by this rule is not large enough for certain use cases. If that is the case, the buffer size can be overridden by placing -b larger_buffer_size into a file within /etc/audit/rules.d directory, replacing larger_file_size with the desired value. The file name should start with a number higher than 10 and lower than 99. | | Rationale: | Without basic configurations, audit may not perform as expected. It may not be able to correctly handle events under stressful conditions, or log events in case of failure. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_audit_basic_configuration | | Identifiers and References | References:
AU-2(a), FAU_GEN.1, SRG-OS-000365-GPOS-00152, SRG-OS-000475-GPOS-00220 | |
|
Rule
Configure auditing of unsuccessful file creations
[ref] | Ensure that unsuccessful attempts to create a file are audited.
The following rules configure audit as described above:
## Unsuccessful file creation (open with O_CREAT)
-a always,exit -F arch=b32 -S openat,open_by_handle_at -F a2&0100 -F exit=-EACCES -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b64 -S openat,open_by_handle_at -F a2&0100 -F exit=-EACCES -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b32 -S open -F a1&0100 -F exit=-EACCES -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b64 -S open -F a1&0100 -F exit=-EACCES -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b32 -S creat -F exit=-EACCES -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b64 -S creat -F exit=-EACCES -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b32 -S openat,open_by_handle_at -F a2&0100 -F exit=-EPERM -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b64 -S openat,open_by_handle_at -F a2&0100 -F exit=-EPERM -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b32 -S open -F a1&0100 -F exit=-EPERM -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b64 -S open -F a1&0100 -F exit=-EPERM -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b32 -S creat -F exit=-EPERM -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
-a always,exit -F arch=b64 -S creat -F exit=-EPERM -F auid>=1000 -F auid!=unset -F key=unsuccessful-create
Load new Audit rules into kernel by running:
augenrules --load
Note: This rule uses a special set of Audit rules to comply with OSPP 4.2.1. You may reuse this rule in different profiles. If you decide to do so, it is recommended that you inspect contents of the file closely and make sure that they are alligned with your needs. | | Rationale: | Unsuccessful file creations might be a sign of a malicious action being performed on the system. Keeping log of such events helps in monitoring and investigation of such actions. | | Severity: | medium | | Rule ID: | xccdf_org.ssgproject.content_rule_audit_create_failed | | Identifiers and References | References:
AU-2(a), FAU_GEN.1.1.c, SRG-OS-000458-GPOS-00203, SRG-OS-000474-GPOS-00219, SRG-OS-000475-GPOS-00220, SRG-OS-000463-GPOS-00207, SRG-OS-000465-GPOS-00209, SRG-OS-000461-GPOS-00205, SRG-APP-000091-CTR-000160, SRG-APP-000492-CTR-001220, SRG-APP-000493-CTR-001225, SRG-APP-000494-CTR-001230, SRG-APP-000500-CTR-001260, SRG-APP-000507-CTR-001295 | |
|