Guide to the Secure Configuration of Debian 8

with profile Standard System Security Profile for Debian 8
This profile contains rules to ensure standard security baseline of a Debian 8 system. Regardless of your system's workload all of these checks should pass.
This guide presents a catalog of security-relevant configuration settings for Debian 8. It is a rendering of content structured in the eXtensible Configuration Checklist Description Format (XCCDF) in order to support security automation. The SCAP content is is available in the scap-security-guide package which is developed at https://www.open-scap.org/security-policies/scap-security-guide.

Providing system administrators with such guidance informs them how to securely configure systems under their control in a variety of network roles. Policy makers and baseline creators can use this catalog of settings, with its associated references to higher-level security control catalogs, in order to assist them in security baseline creation. This guide is a catalog, not a checklist, and satisfaction of every item is not likely to be possible or sensible in many operational scenarios. However, the XCCDF format enables granular selection and adjustment of settings, and their association with OVAL and OCIL content provides an automated checking capability. Transformations of this document, and its associated automated checking content, are capable of providing baselines that meet a diverse set of policy objectives. Some example XCCDF Profiles, which are selections of items that form checklists and can be used as baselines, are available with this guide. They can be processed, in an automated fashion, with tools that support the Security Content Automation Protocol (SCAP). The DISA STIG, which provides required settings for US Department of Defense systems, is one example of a baseline created from this guidance.
Do not attempt to implement any of the settings in this guide without first testing them in a non-operational environment. The creators of this guidance assume no responsibility whatsoever for its use by other parties, and makes no guarantees, expressed or implied, about its quality, reliability, or any other characteristic.

Profile Information

Profile TitleStandard System Security Profile for Debian 8
Profile IDxccdf_org.ssgproject.content_profile_standard

CPE Platforms

  • cpe:/o:debianproject:debian:8

Revision History

Current version: 0.1.44

  • draft (as of 2019-05-03)

Table of Contents

  1. Services
    1. Cron and At Daemons
    2. Network Time Protocol
    3. Deprecated services
    4. SSH Server
  2. System Settings
    1. Installing and Maintaining Software
    2. Configure Syslog
    3. System Accounting with auditd
    4. File Permissions and Masks

Checklist

Group   Guide to the Secure Configuration of Debian 8   Group contains 19 groups and 44 rules
Group   Services   Group contains 5 groups and 14 rules

[ref]   The best protection against vulnerable software is running less software. This section describes how to review the software which Debian 8 installs on a system and disable software which is not needed. It then enumerates the software packages installed on a default Debian 8 system and provides guidance about which ones can be safely disabled.

Debian 8 provides a convenient minimal install option that essentially installs the bare necessities for a functional system. When building Debian 8 systems, it is highly recommended to select the minimal packages and then build up the system from there.

Group   Cron and At Daemons   Group contains 2 rules

[ref]   The cron and at services are used to allow commands to be executed at a later time. The cron service is required by almost all systems to perform necessary maintenance tasks, while at may or may not be required on a given system. Both daemons should be configured defensively.

Rule   Enable cron Service   [ref]

The crond service is used to execute commands at preconfigured times. It is required by almost all systems to perform necessary maintenance tasks, such as notifying root of system activity. The cron service can be enabled with the following command:

$ sudo systemctl enable cron.service

Rationale:

Due to its usage for maintenance and security-supporting tasks, enabling the cron daemon is essential.

Severity: 
medium
Identifiers and References

References:  11, 14, 3, 9, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS05.02, DSS05.05, DSS06.06, 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, 4.3.4.3.2, 4.3.4.3.3, 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, 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, A.9.1.2, CM-7, PR.IP-1, PR.PT-3

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
- name: Enable service cron
  service:
    name: cron
    enabled: 'yes'
    state: started
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - service_cron_enabled
    - medium_severity
    - enable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-CM-7

Rule   Install the cron service   [ref]

The Cron service should be installed.

Rationale:

The cron service allow periodic job execution, needed for almost all administrative tasks and services (software update, log rotating, etc.). Access to cron service should be restricted to administrative accounts only.

Severity: 
medium
Identifiers and References

References:  NT28(R50), 11, 14, 3, 9, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS05.02, DSS05.05, DSS06.06, 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, 4.3.4.3.2, 4.3.4.3.3, 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, 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, A.9.1.2, CM-7, PR.IP-1, PR.PT-3

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
- name: Ensure cron is installed
  package:
    name: cron
    state: present
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - package_cron_installed
    - medium_severity
    - enable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-CM-7
Remediation Puppet snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
include install_cron

class install_cron {
  package { 'cron':
    ensure => 'installed',
  }
}
Group   Network Time Protocol   Group contains 2 rules

[ref]   The Network Time Protocol is used to manage the system clock over a network. Computer clocks are not very accurate, so time will drift unpredictably on unmanaged systems. Central time protocols can be used both to ensure that time is consistent among a network of systems, and that their time is consistent with the outside world.

If every system on a network reliably reports the same time, then it is much easier to correlate log messages in case of an attack. In addition, a number of cryptographic protocols (such as Kerberos) use timestamps to prevent certain types of attacks. If your network does not have synchronized time, these protocols may be unreliable or even unusable.

Depending on the specifics of the network, global time accuracy may be just as important as local synchronization, or not very important at all. If your network is connected to the Internet, using a public timeserver (or one provided by your enterprise) provides globally accurate timestamps which may be essential in investigating or responding to an attack which originated outside of your network.

A typical network setup involves a small number of internal systems operating as NTP servers, and the remainder obtaining time information from those internal servers.

There is a choice between the daemons ntpd and chronyd, which are available from the repositories in the ntp and chrony packages respectively.

The default chronyd daemon can work well when external time references are only intermittently accesible, can perform well even when the network is congested for longer periods of time, can usually synchronize the clock faster and with better time accuracy, and quickly adapts to sudden changes in the rate of the clock, for example, due to changes in the temperature of the crystal oscillator. Chronyd should be considered for all systems which are frequently suspended or otherwise intermittently disconnected and reconnected to a network. Mobile and virtual systems for example.

The ntpd NTP daemon fully supports NTP protocol version 4 (RFC 5905), including broadcast, multicast, manycast clients and servers, and the orphan mode. It also supports extra authentication schemes based on public-key cryptography (RFC 5906). The NTP daemon (ntpd) should be considered for systems which are normally kept permanently on. Systems which are required to use broadcast or multicast IP, or to perform authentication of packets with the Autokey protocol, should consider using ntpd.

Refer to https://docs.fedoraproject.org/en-US/fedora/rawhide/system-administrators-guide/servers/Configuring_NTP_Using_the_chrony_Suite/ for more detailed comparison of features of chronyd and ntpd daemon features respectively, and for further guidance how to choose between the two NTP daemons.

The upstream manual pages at http://chrony.tuxfamily.org/manual.html for chronyd and http://www.ntp.org for ntpd provide additional information on the capabilities and configuration of each of the NTP daemons.

Rule   Install the ntp service   [ref]

The ntpd service should be installed.

Rationale:

Time synchronization (using NTP) is required by almost all network and administrative tasks (syslog, cryptographic based services (authentication, etc.), etc.). Ntpd is regulary maintained and updated, supporting security features such as RFC 5906.

Severity: 
high
Identifiers and References

References:  NT012(R03), 1, 14, 15, 16, 3, 5, 6, APO11.04, BAI03.05, DSS05.04, DSS05.07, MEA02.01, CCI-000160, 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, A.12.4.1, A.12.4.2, A.12.4.3, A.12.4.4, A.12.7.1, AU-8(1), PR.PT-1, Req-10.4

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
- name: Ensure ntp is installed
  package:
    name: ntp
    state: present
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - package_ntp_installed
    - high_severity
    - enable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-10.4
    - NIST-800-53-AU-8(1)
Remediation Puppet snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
include install_ntp

class install_ntp {
  package { 'ntp':
    ensure => 'installed',
  }
}

Rule   Enable the NTP Daemon   [ref]

The ntpd service can be enabled with the following command:

$ sudo systemctl enable ntpd.service

Rationale:

Enabling the ntpd service ensures that the ntpd service will be running and that the system will synchronize its time to any servers specified. This is important whether the system is configured to be a client (and synchronize only its own clock) or it is also acting as an NTP server to other systems. Synchronizing time is essential for authentication services such as Kerberos, but it is also important for maintaining accurate logs and auditing possible security breaches.

The NTP daemon offers all of the functionality of ntpdate, which is now deprecated. Additional information on this is available at http://support.ntp.org/bin/view/Dev/DeprecatingNtpdate.

Severity: 
high
Identifiers and References

References:  NT012(R03), 1, 14, 15, 16, 3, 5, 6, APO11.04, BAI03.05, DSS05.04, DSS05.07, MEA02.01, CCI-000160, 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, A.12.4.1, A.12.4.2, A.12.4.3, A.12.4.4, A.12.7.1, AU-8(1), PR.PT-1, Req-10.4

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
- name: Enable service ntp
  service:
    name: ntp
    enabled: 'yes'
    state: started
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - service_ntp_enabled
    - high_severity
    - enable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-10.4
    - NIST-800-53-AU-8(1)
Group   Deprecated services   Group contains 5 rules

[ref]   Some deprecated software services impact the overall system security due to their behavior (leak of confidentiality in network exchange, usage as uncontrolled communication channel, risk associated with the service due to its old age, etc.

Rule   Uninstall the nis package   [ref]

The support for Yellowpages should not be installed unless it is required.

Rationale:

NIS is the historical SUN service for central account management, more and more replaced by LDAP. NIS does not support efficiently security constraints, ACL, etc. and should not be used.

Severity: 
low
Identifiers and References
Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:disable
# Function to remove packages on RHEL, Fedora, Debian, and possibly other systems.
#
# Example Call(s):
#
#     package_remove telnet-server
#
function package_remove {

# Load function arguments into local variables
local package="$1"

# Check sanity of the input
if [ $# -ne "1" ]
then
  echo "Usage: package_remove 'package_name'"
  echo "Aborting."
  exit 1
fi

if which dnf ; then
  if rpm -q --quiet "$package"; then
    dnf remove -y "$package"
  fi
elif which yum ; then
  if rpm -q --quiet "$package"; then
    yum remove -y "$package"
  fi
elif which apt-get ; then
  apt-get remove -y "$package"
else
  echo "Failed to detect available packaging system, tried dnf, yum and apt-get!"
  echo "Aborting."
  exit 1
fi

}

package_remove nis
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
- name: Ensure nis is removed
  package:
    name: nis
    state: absent
  tags:
    - package_nis_removed
    - low_severity
    - disable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
Remediation Puppet snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
include remove_nis

class remove_nis {
  package { 'nis':
    ensure => 'purged',
  }
}

Rule   Uninstall the telnet server   [ref]

The telnet daemon should be uninstalled.

Rationale:

telnet allows clear text communications, and does not protect any data transmission between client and server. Any confidential data can be listened and no integrity checking is made.

Severity: 
high
Identifiers and References

References:  NT007(R03), 11, 12, 14, 15, 3, 8, 9, APO13.01, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS01.04, DSS05.02, DSS05.03, DSS05.05, DSS06.06, 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, 4.3.4.3.2, 4.3.4.3.3, 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, 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.11.2.6, A.12.1.2, A.12.5.1, A.12.6.2, A.13.1.1, A.13.2.1, A.14.1.3, A.14.2.2, A.14.2.3, A.14.2.4, A.6.2.1, A.6.2.2, A.9.1.2, AC-17(8), CM-7, PR.AC-3, PR.IP-1, PR.PT-3, PR.PT-4

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:disable
# Function to remove packages on RHEL, Fedora, Debian, and possibly other systems.
#
# Example Call(s):
#
#     package_remove telnet-server
#
function package_remove {

# Load function arguments into local variables
local package="$1"

# Check sanity of the input
if [ $# -ne "1" ]
then
  echo "Usage: package_remove 'package_name'"
  echo "Aborting."
  exit 1
fi

if which dnf ; then
  if rpm -q --quiet "$package"; then
    dnf remove -y "$package"
  fi
elif which yum ; then
  if rpm -q --quiet "$package"; then
    yum remove -y "$package"
  fi
elif which apt-get ; then
  apt-get remove -y "$package"
else
  echo "Failed to detect available packaging system, tried dnf, yum and apt-get!"
  echo "Aborting."
  exit 1
fi

}

package_remove telnetd
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
- name: Ensure telnetd is removed
  package:
    name: telnetd
    state: absent
  tags:
    - package_telnetd_removed
    - high_severity
    - disable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AC-17(8)
    - NIST-800-53-CM-7
Remediation Puppet snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
include remove_telnetd

class remove_telnetd {
  package { 'telnetd':
    ensure => 'purged',
  }
}

Rule   Uninstall the ntpdate package   [ref]

ntpdate is a historical ntp synchronization client for unixes. It sould be uninstalled.

Rationale:

ntpdate is an old not security-compliant ntp client. It should be replaced by modern ntp clients such as ntpd, able to use cryptographic mechanisms integrated in NTP.

Severity: 
low
Identifiers and References
Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:disable
# Function to remove packages on RHEL, Fedora, Debian, and possibly other systems.
#
# Example Call(s):
#
#     package_remove telnet-server
#
function package_remove {

# Load function arguments into local variables
local package="$1"

# Check sanity of the input
if [ $# -ne "1" ]
then
  echo "Usage: package_remove 'package_name'"
  echo "Aborting."
  exit 1
fi

if which dnf ; then
  if rpm -q --quiet "$package"; then
    dnf remove -y "$package"
  fi
elif which yum ; then
  if rpm -q --quiet "$package"; then
    yum remove -y "$package"
  fi
elif which apt-get ; then
  apt-get remove -y "$package"
else
  echo "Failed to detect available packaging system, tried dnf, yum and apt-get!"
  echo "Aborting."
  exit 1
fi

}

package_remove ntpdate
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
- name: Ensure ntpdate is removed
  package:
    name: ntpdate
    state: absent
  tags:
    - package_ntpdate_removed
    - low_severity
    - disable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
Remediation Puppet snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
include remove_ntpdate

class remove_ntpdate {
  package { 'ntpdate':
    ensure => 'purged',
  }
}

Rule   Uninstall the ssl compliant telnet server   [ref]

The telnet daemon, even with ssl support, should be uninstalled.

Rationale:

telnet, even with ssl support, should not be installed. When remote shell is required, up-to-date ssh daemon can be used.

Severity: 
high
Identifiers and References

References:  NT007(R02), 11, 12, 14, 15, 3, 8, 9, APO13.01, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS01.04, DSS05.02, DSS05.03, DSS05.05, DSS06.06, 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, 4.3.4.3.2, 4.3.4.3.3, 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, 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.11.2.6, A.12.1.2, A.12.5.1, A.12.6.2, A.13.1.1, A.13.2.1, A.14.1.3, A.14.2.2, A.14.2.3, A.14.2.4, A.6.2.1, A.6.2.2, A.9.1.2, AC-17(8), CM-7, PR.AC-3, PR.IP-1, PR.PT-3, PR.PT-4

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:disable
# Function to remove packages on RHEL, Fedora, Debian, and possibly other systems.
#
# Example Call(s):
#
#     package_remove telnet-server
#
function package_remove {

# Load function arguments into local variables
local package="$1"

# Check sanity of the input
if [ $# -ne "1" ]
then
  echo "Usage: package_remove 'package_name'"
  echo "Aborting."
  exit 1
fi

if which dnf ; then
  if rpm -q --quiet "$package"; then
    dnf remove -y "$package"
  fi
elif which yum ; then
  if rpm -q --quiet "$package"; then
    yum remove -y "$package"
  fi
elif which apt-get ; then
  apt-get remove -y "$package"
else
  echo "Failed to detect available packaging system, tried dnf, yum and apt-get!"
  echo "Aborting."
  exit 1
fi

}

package_remove telnetd-ssl
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
- name: Ensure telnetd-ssl is removed
  package:
    name: telnetd-ssl
    state: absent
  tags:
    - package_telnetd-ssl_removed
    - high_severity
    - disable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AC-17(8)
    - NIST-800-53-CM-7
Remediation Puppet snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
include remove_telnetd-ssl

class remove_telnetd-ssl {
  package { 'telnetd-ssl':
    ensure => 'purged',
  }
}

Rule   Uninstall the inet-based telnet server   [ref]

The inet-based telnet daemon should be uninstalled.

Rationale:

telnet allows clear text communications, and does not protect any data transmission between client and server. Any confidential data can be listened and no integrity checking is made.

Severity: 
high
Identifiers and References

References:  NT007(R03), 11, 12, 14, 15, 3, 8, 9, APO13.01, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS01.04, DSS05.02, DSS05.03, DSS05.05, DSS06.06, 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, 4.3.4.3.2, 4.3.4.3.3, 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, 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.11.2.6, A.12.1.2, A.12.5.1, A.12.6.2, A.13.1.1, A.13.2.1, A.14.1.3, A.14.2.2, A.14.2.3, A.14.2.4, A.6.2.1, A.6.2.2, A.9.1.2, AC-17(8), CM-7, PR.AC-3, PR.IP-1, PR.PT-3, PR.PT-4

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:disable
# Function to remove packages on RHEL, Fedora, Debian, and possibly other systems.
#
# Example Call(s):
#
#     package_remove telnet-server
#
function package_remove {

# Load function arguments into local variables
local package="$1"

# Check sanity of the input
if [ $# -ne "1" ]
then
  echo "Usage: package_remove 'package_name'"
  echo "Aborting."
  exit 1
fi

if which dnf ; then
  if rpm -q --quiet "$package"; then
    dnf remove -y "$package"
  fi
elif which yum ; then
  if rpm -q --quiet "$package"; then
    yum remove -y "$package"
  fi
elif which apt-get ; then
  apt-get remove -y "$package"
else
  echo "Failed to detect available packaging system, tried dnf, yum and apt-get!"
  echo "Aborting."
  exit 1
fi

}

package_remove inetutils-telnetd
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
- name: Ensure inetutils-telnetd is removed
  package:
    name: inetutils-telnetd
    state: absent
  tags:
    - package_inetutils-telnetd_removed
    - high_severity
    - disable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AC-17(8)
    - NIST-800-53-CM-7
Remediation Puppet snippet:   (show)

Complexity:low
Disruption:low
Strategy:disable
include remove_inetutils-telnetd

class remove_inetutils-telnetd {
  package { 'inetutils-telnetd':
    ensure => 'purged',
  }
}
Group   SSH Server   Group contains 1 group and 5 rules

[ref]   The SSH protocol is recommended for remote login and remote file transfer. SSH provides confidentiality and integrity for data exchanged between two systems, as well as server authentication, through the use of public key cryptography. The implementation included with the system is called OpenSSH, and more detailed documentation is available from its website, http://www.openssh.org. Its server program is called sshd and provided by the RPM package openssh-server.

Group   Configure OpenSSH Server if Necessary   Group contains 5 rules

[ref]   If the system needs to act as an SSH server, then certain changes should be made to the OpenSSH daemon configuration file /etc/ssh/sshd_config. The following recommendations can be applied to this file. See the sshd_config(5) man page for more detailed information.

Rule   Disable SSH Access via Empty Passwords   [ref]

To explicitly disallow SSH login from accounts with empty passwords, add or correct the following line in /etc/ssh/sshd_config:

PermitEmptyPasswords no

Any accounts with empty passwords should be disabled immediately, and PAM configuration should prevent users from being able to assign themselves empty passwords.

Rationale:

Configuring this setting for the SSH daemon provides additional assurance that remote login via SSH will require a password, even in the event of misconfiguration elsewhere.

Severity: 
high
Identifiers and References

References:  NT007(R17), 5.2.9, 11, 12, 13, 14, 15, 16, 18, 3, 5, 9, 5.5.6, APO01.06, BAI10.01, BAI10.02, BAI10.03, BAI10.05, DSS05.02, DSS05.04, DSS05.05, DSS05.07, DSS06.02, DSS06.03, DSS06.06, 3.1.1, 3.1.5, CCI-000366, 164.308(a)(4)(i), 164.308(b)(1), 164.308(b)(3), 164.310(b), 164.312(e)(1), 164.312(e)(2)(ii), 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, 4.3.4.3.2, 4.3.4.3.3, 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, SR 5.2, SR 7.6, A.10.1.1, A.11.1.4, A.11.1.5, A.11.2.1, A.12.1.2, A.12.5.1, A.12.6.2, 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.14.2.2, A.14.2.3, A.14.2.4, 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.9.2.3, A.9.4.1, A.9.4.4, A.9.4.5, AC-3, AC-6, AC-17(b), CM-6(b), PR.AC-4, PR.AC-6, PR.DS-5, PR.IP-1, PR.PT-3, FIA_AFL.1, SRG-OS-000480-GPOS-00229, SRG-OS-000480-VMM-002000

Rule   Set SSH Client Alive Max Count   [ref]

To ensure the SSH idle timeout occurs precisely when the ClientAliveInterval is set, edit /etc/ssh/sshd_config as follows:

ClientAliveCountMax 0

Rationale:

This ensures a user login will be terminated as soon as the ClientAliveInterval is reached.

Severity: 
medium
Identifiers and References

References:  5.2.12, 1, 12, 13, 14, 15, 16, 18, 3, 5, 7, 8, 5.5.6, APO13.01, BAI03.01, BAI03.02, BAI03.03, DSS01.03, DSS03.05, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, 3.1.11, CCI-001133, CCI-002361, 164.308(a)(4)(i), 164.308(b)(1), 164.308(b)(3), 164.310(b), 164.312(e)(1), 164.312(e)(2)(ii), 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, 4.3.4.3.3, 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 6.2, A.12.4.1, A.12.4.3, A.14.1.1, A.14.2.1, A.14.2.5, A.18.1.4, A.6.1.2, A.6.1.5, 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, AC-2(5), SA-8, AC-12, AC-17(b), DE.CM-1, DE.CM-3, PR.AC-1, PR.AC-4, PR.AC-6, PR.AC-7, PR.IP-2, SRG-OS-000163-GPOS-00072, SRG-OS-000279-GPOS-00109A, SRG-OS-000480-VMM-002000

Rule   Set SSH Idle Timeout Interval   [ref]

SSH allows administrators to set an idle timeout interval. After this interval has passed, the idle user will be automatically logged out.

To set an idle timeout interval, edit the following line in /etc/ssh/sshd_config as follows:

ClientAliveInterval 300
The timeout interval is given in seconds. To have a timeout of 15 minutes, set interval to 900.

If a shorter timeout has already been set for the login shell, that value will preempt any SSH setting made here. Keep in mind that some processes may stop SSH from correctly detecting that the user is idle.

Rationale:

Terminating an idle ssh session within a short time period reduces the window of opportunity for unauthorized personnel to take control of a management session enabled on the console or console port that has been let unattended.

Severity: 
medium
Identifiers and References

References:  SA-8, PR.IP-2, 5.2.12, 1, 12, 13, 14, 15, 16, 18, 3, 5, 7, 8, 5.5.6, APO13.01, BAI03.01, BAI03.02, BAI03.03, DSS01.03, DSS03.05, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, 3.1.11, CCI-001133, CCI-002361, 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, 4.3.4.3.3, 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 6.2, A.12.4.1, A.12.4.3, A.14.1.1, A.14.2.1, A.14.2.5, A.18.1.4, A.6.1.2, A.6.1.5, 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, AC-2(5), SA-8(i), AC-12, AC-17(b), DE.CM-1, DE.CM-3, PR.AC-1, PR.AC-4, PR.AC-6, PR.AC-7, PR.IP-2, Req-8.1.8, SRG-OS-000163-GPOS-00072, SRG-OS-000279-GPOS-00109, SRG-OS-000480-VMM-002000

Rule   Allow Only SSH Protocol 2   [ref]

Only SSH protocol version 2 connections should be permitted. The default setting in /etc/ssh/sshd_config is correct, and can be verified by ensuring that the following line appears:

Protocol 2

Warning:  As of openssh-server version 7.4 and above, the only protocol supported is version 2, and line
Protocol 2
in /etc/ssh/sshd_config is not necessary.
Rationale:

SSH protocol version 1 is an insecure implementation of the SSH protocol and has many well-known vulnerability exploits. Exploits of the SSH daemon could provide immediate root access to the system.

Severity: 
high
Identifiers and References

References:  NT007(R1), AC-17(7), PR.AC-3, PR.PT-4, 5.2.2, 1, 12, 15, 16, 5, 8, 5.5.6, APO13.01, DSS01.04, DSS05.02, DSS05.03, DSS05.04, DSS05.05, DSS05.07, DSS05.10, DSS06.03, DSS06.10, 3.1.13, 3.5.4, CCI-000197, CCI-000366, 164.308(a)(4)(i), 164.308(b)(1), 164.308(b)(3), 164.310(b), 164.312(e)(1), 164.312(e)(2)(ii), 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 1.13, 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 2.6, 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.11.2.6, A.13.1.1, A.13.2.1, A.14.1.3, A.18.1.4, A.6.2.1, A.6.2.2, 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, AC-17(b), AC-17(8).1(ii), IA-5(1)(c), PR.AC-1, PR.AC-3, PR.AC-6, PR.AC-7, PR.PT-4, SRG-OS-000074-GPOS-00042, SRG-OS-000480-GPOS-00227, SRG-OS-000033-VMM-000140

Group   System Settings   Group contains 12 groups and 30 rules

[ref]   Contains rules that check correct system settings.

Group   Installing and Maintaining Software   Group contains 1 group and 5 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   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
Identifiers and References

References:  NT28(R12), 1.1.13, 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, SC-32(1), PR.PT-4, SRG-OS-000480-GPOS-00227

Rule   Ensure /tmp Located On Separate Partition   [ref]

The /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 /tmp partition is used as temporary storage by many programs. Placing /tmp in its own partition enables the setting of more restrictive mount options, which can help protect programs which use it.

Severity: 
low
Identifiers and References

References:  NT28(R12), 1.1.2, 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, SC-32(1), 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
Identifiers and References

References:  NT28(R12), 1.1.6, 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, SC-32(1), PR.PT-4, SRG-OS-000480-GPOS-00227, SRG-OS-000341-VMM-001220

Rule   Ensure /var/log/audit Located On Separate Partition   [ref]

Audit logs are stored in the /var/log/audit directory. Ensure that it has its own partition or logical volume at installation time, or migrate it later 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
Identifiers and References

References:  1.1.12, 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, 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, AU-4, AU-9, SC-32(1), PR.DS-4, PR.PT-1, PR.PT-4, SRG-OS-000480-GPOS-00227, SRG-OS-000341-VMM-001220

Rule   Ensure /var/log Located On Separate Partition   [ref]

System logs are stored in the /var/log directory. Ensure that it 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: 
medium
Identifiers and References

References:  NT28(R12), NT28(R47), 1.1.11, 1, 12, 14, 15, 16, 3, 5, 6, 8, APO11.04, APO13.01, BAI03.05, DSS05.02, DSS05.04, DSS05.07, MEA02.01, 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, AU-9, SC-32, PR.PT-1, PR.PT-4

Group   Configure Syslog   Group contains 2 groups and 6 rules

[ref]   The syslog service has been the default Unix logging mechanism for many years. It has a number of downsides, including inconsistent log format, lack of authentication for received messages, and lack of authentication, encryption, or reliable transport for messages sent over a network. However, due to its long history, syslog is a de facto standard which is supported by almost all Unix applications.

In Debian 8, rsyslog has replaced ksyslogd as the syslog daemon of choice, and it includes some additional security features such as reliable, connection-oriented (i.e. TCP) transmission of logs, the option to log to database formats, and the encryption of log data en route to a central logging server. This section discusses how to configure rsyslog for best effect, and how to use tools provided with the system to maintain and monitor logs.

Group   Ensure Proper Configuration of Log Files   Group contains 3 rules

[ref]   The file /etc/rsyslog.conf controls where log message are written. These are controlled by lines called rules, which consist of a selector and an action. These rules are often customized depending on the role of the system, the requirements of the environment, and whatever may enable the administrator to most effectively make use of log data. The default rules in Debian 8 are:

*.info;mail.none;authpriv.none;cron.none                /var/log/messages
authpriv.*                                              /var/log/secure
mail.*                                                  -/var/log/maillog
cron.*                                                  /var/log/cron
*.emerg                                                 *
uucp,news.crit                                          /var/log/spooler
local7.*                                                /var/log/boot.log
See the man page rsyslog.conf(5) for more information. Note that the rsyslog daemon can be configured to use a timestamp format that some log processing programs may not understand. If this occurs, edit the file /etc/rsyslog.conf and add or edit the following line:
$ ActionFileDefaultTemplate RSYSLOG_TraditionalFileFormat

Rule   Ensure Log Files Are Owned By Appropriate User   [ref]

The owner of all log files written by rsyslog should be adm. These log files are determined by the second part of each Rule line in /etc/rsyslog.conf and typically all appear in /var/log. For each log file LOGFILE referenced in /etc/rsyslog.conf, run the following command to inspect the file's owner:

$ ls -l LOGFILE
If the owner is not adm, run the following command to correct this:
$ sudo chown adm LOGFILE

Rationale:

The log files generated by rsyslog contain valuable information regarding system configuration, user authentication, and other such information. Log files should be protected from unauthorized access.

Severity: 
medium
Identifiers and References

References:  NT28(R46), NT28(R5), 12, 13, 14, 15, 16, 18, 3, 5, APO01.06, DSS05.04, DSS05.07, DSS06.02, CCI-001314, 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, AC-6, SI-11, PR.AC-4, PR.DS-5, Req-10.5.1, Req-10.5.2

Rule   Ensure Log Files Are Owned By Appropriate Group   [ref]

The group-owner of all log files written by rsyslog should be adm. These log files are determined by the second part of each Rule line in /etc/rsyslog.conf and typically all appear in /var/log. For each log file LOGFILE referenced in /etc/rsyslog.conf, run the following command to inspect the file's group owner:

$ ls -l LOGFILE
If the owner is not adm, run the following command to correct this:
$ sudo chgrp adm LOGFILE

Rationale:

The log files generated by rsyslog contain valuable information regarding system configuration, user authentication, and other such information. Log files should be protected from unauthorized access.

Severity: 
medium
Identifiers and References

References:  NT28(R46), NT28(R5), 12, 13, 14, 15, 16, 18, 3, 5, APO01.06, DSS05.04, DSS05.07, DSS06.02, CCI-001314, 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, AC-6, SI-11, PR.AC-4, PR.DS-5, Req-10.5.1, Req-10.5.2

Rule   Ensure System Log Files Have Correct Permissions   [ref]

The file permissions for all log files written by rsyslog should be set to 600, or more restrictive. These log files are determined by the second part of each Rule line in /etc/rsyslog.conf and typically all appear in /var/log. For each log file LOGFILE referenced in /etc/rsyslog.conf, run the following command to inspect the file's permissions:

$ ls -l LOGFILE
If the permissions are not 600 or more restrictive, run the following command to correct this:
$ sudo chmod 0600 LOGFILE
"

Rationale:

Log files can contain valuable information regarding system configuration. If the system log files are not protected unauthorized users could change the logged data, eliminating their forensic value.

Severity: 
medium
Identifiers and References

References:  5.1.4, NT28(R36), 4.2.1.3, CCI-001314, SI-11, Req-10.5.1, Req-10.5.2

Group   Ensure All Logs are Rotated by logrotate   Group contains 1 rule

[ref]   Edit the file /etc/logrotate.d/rsyslog. Find the first line, which should look like this (wrapped for clarity):

/var/log/messages /var/log/secure /var/log/maillog /var/log/spooler \
  /var/log/boot.log /var/log/cron {
Edit this line so that it contains a one-space-separated listing of each log file referenced in /etc/rsyslog.conf.

All logs in use on a system must be rotated regularly, or the log files will consume disk space over time, eventually interfering with system operation. The file /etc/logrotate.d/syslog is the configuration file used by the logrotate program to maintain all log files written by syslog. By default, it rotates logs weekly and stores four archival copies of each log. These settings can be modified by editing /etc/logrotate.conf, but the defaults are sufficient for purposes of this guide.

Note that logrotate is run nightly by the cron job /etc/cron.daily/logrotate. If particularly active logs need to be rotated more often than once a day, some other mechanism must be used.

Rule   Ensure Logrotate Runs Periodically   [ref]

The logrotate utility allows for the automatic rotation of log files. The frequency of rotation is specified in /etc/logrotate.conf, which triggers a cron task. To configure logrotate to run daily, add or correct the following line in /etc/logrotate.conf:

# rotate log files frequency
daily

Rationale:

Log files that are not properly rotated run the risk of growing so large that they fill up the /var/log partition. Valuable logging information could be lost if the /var/log partition becomes full.

Severity: 
medium
Identifiers and References

References:  1, 14, 15, 16, 3, 5, 6, APO11.04, BAI03.05, 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, A.12.4.1, A.12.4.2, A.12.4.3, A.12.4.4, A.12.7.1, AU-9, PR.PT-1, Req-10.7

Remediation Shell script:   (show)


LOGROTATE_CONF_FILE="/etc/logrotate.conf"
CRON_DAILY_LOGROTATE_FILE="/etc/cron.daily/logrotate"

# daily rotation is configured
grep -q "^daily$" $LOGROTATE_CONF_FILE|| echo "daily" >> $LOGROTATE_CONF_FILE

# remove any line configuring weekly, monthly or yearly rotation
sed -i -r "/^(weekly|monthly|yearly)$/d" $LOGROTATE_CONF_FILE

# configure cron.daily if not already
if ! grep -q "^[[:space:]]*/usr/sbin/logrotate[[:alnum:][:blank:][:punct:]]*$LOGROTATE_CONF_FILE$" $CRON_DAILY_LOGROTATE_FILE; then
	echo "#!/bin/sh" > $CRON_DAILY_LOGROTATE_FILE
	echo "/usr/sbin/logrotate $LOGROTATE_CONF_FILE" >> $CRON_DAILY_LOGROTATE_FILE
fi

Rule   Enable rsyslog Service   [ref]

The rsyslog service provides syslog-style logging by default on Debian 8. The rsyslog service can be enabled with the following command:

$ sudo systemctl enable rsyslog.service

Rationale:

The rsyslog service must be running in order to provide logging services, which are essential to system administration.

Severity: 
medium
Identifiers and References

References:  5.1.2, NT28(R5), NT28(R46), 4.2.1.1, 1, 12, 13, 14, 15, 16, 2, 3, 5, 6, 7, 8, 9, APO10.01, APO10.03, APO10.04, APO10.05, APO11.04, APO13.01, BAI03.05, BAI04.04, DSS01.03, DSS03.05, DSS05.02, DSS05.04, DSS05.05, DSS05.07, MEA01.01, MEA01.02, MEA01.03, MEA01.04, MEA01.05, MEA02.01, CCI-001311, CCI-001312, CCI-001557, CCI-001851, 164.312(a)(2)(ii), 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, SR 7.1, SR 7.2, 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.14.2.7, A.15.2.1, A.15.2.2, A.17.2.1, AU-4(1), AU-12, DE.CM-1, DE.CM-3, DE.CM-7, ID.SC-4, PR.DS-4, PR.PT-1

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
- name: Enable service rsyslog
  service:
    name: rsyslog
    enabled: 'yes'
    state: started
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - service_rsyslog_enabled
    - medium_severity
    - enable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AU-4(1)
    - NIST-800-53-AU-12

Rule   Ensure rsyslog is Installed   [ref]

Rsyslog is installed by default. The rsyslog package can be installed with the following command:

 $ apt-get install rsyslog

Rationale:

The rsyslog package provides the rsyslog daemon, which provides system logging services.

Severity: 
medium
Identifiers and References

References:  5.1.1, NT28(R5), NT28(R46), 4.2.3, 1, 14, 15, 16, 3, 5, 6, APO11.04, BAI03.05, DSS05.04, DSS05.07, MEA02.01, CCI-001311, CCI-001312, 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, A.12.4.1, A.12.4.2, A.12.4.3, A.12.4.4, A.12.7.1, AU-9(2), PR.PT-1

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
- name: Ensure rsyslog is installed
  package:
    name: rsyslog
    state: present
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - package_rsyslog_installed
    - medium_severity
    - enable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AU-9(2)
Remediation Puppet snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
include install_rsyslog

class install_rsyslog {
  package { 'rsyslog':
    ensure => 'installed',
  }
}
Group   System Accounting with auditd   Group contains 2 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 Fedora Documentation available at https://access.redhat.com/documentation/en-US/Red_Hat_Enterprise_Linux/7/html/SELinux_Users_and_Administrators_Guide/sect-Security-Enhanced_Linux-Troubleshooting-Fixing_Problems.html#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".

Rule   Enable auditd Service   [ref]

The auditd service is an essential userspace component of the Linux Auditing System, as it is responsible for writing audit records to disk. The auditd service can be enabled with the following command:

$ sudo systemctl enable auditd.service

Rationale:

Without establishing what type of events occurred, it would be difficult to establish, correlate, and investigate the events leading up to an outage or attack. Ensuring the auditd service is active ensures audit records generated by the kernel are appropriately recorded.

Additionally, a properly configured audit subsystem ensures that actions of individual system users can be uniquely traced to those users so they can be held accountable for their actions.

Severity: 
high
Identifiers and References

References:  4.1.2, 1, 11, 12, 13, 14, 15, 16, 19, 2, 3, 4, 5, 6, 7, 8, 9, 5.4.1.1, APO10.01, APO10.03, APO10.04, APO10.05, APO11.04, APO12.06, APO13.01, BAI03.05, BAI08.02, DSS01.03, DSS01.04, DSS02.02, DSS02.04, DSS02.07, DSS03.01, DSS03.05, DSS05.02, DSS05.03, DSS05.04, DSS05.05, DSS05.07, MEA01.01, MEA01.02, MEA01.03, MEA01.04, MEA01.05, MEA02.01, 3.3.1, 3.3.2, 3.3.6, CCI-000126, CCI-000130, CCI-000131, CCI-000132, CCI-000133, CCI-000134, 164.308(a)(1)(ii)(D), 164.308(a)(5)(ii)(C), 164.310(a)(2)(iv), 164.310(d)(2)(iii), 164.312(b), 4.2.3.10, 4.3.2.6.7, 4.3.3.3.9, 4.3.3.5.8, 4.3.3.6.6, 4.3.4.4.7, 4.3.4.5.6, 4.3.4.5.7, 4.3.4.5.8, 4.4.2.1, 4.4.2.2, 4.4.2.4, SR 1.13, SR 2.10, SR 2.11, SR 2.12, SR 2.6, 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 6.1, SR 6.2, SR 7.1, SR 7.6, A.11.2.6, 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, A.14.2.7, A.15.2.1, A.15.2.2, A.16.1.4, A.16.1.5, A.16.1.7, A.6.2.1, A.6.2.2, AC-2(g), AU-3, AC-17(1), AU-1(b), AU-10, AU-12(a), AU-12(c), AU-14(1), IR-5, DE.AE-3, DE.AE-5, DE.CM-1, DE.CM-3, DE.CM-7, ID.SC-4, PR.AC-3, PR.PT-1, PR.PT-4, RS.AN-1, RS.AN-4, Req-10.1, SRG-OS-000038-GPOS-00016, SRG-OS-000039-GPOS-00017, SRG-OS-000042-GPOS-00021, SRG-OS-000254-GPOS-00095, SRG-OS-000255-GPOS-00096, SRG-OS-000037-VMM-000150, SRG-OS-000063-VMM-000310, SRG-OS-000038-VMM-000160, SRG-OS-000039-VMM-000170, SRG-OS-000040-VMM-000180, SRG-OS-000041-VMM-000190

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
- name: Enable service auditd
  service:
    name: auditd
    enabled: 'yes'
    state: started
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - service_auditd_enabled
    - high_severity
    - enable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-10.1
    - NIST-800-171-3.3.1
    - NIST-800-171-3.3.2
    - NIST-800-171-3.3.6
    - NIST-800-53-AC-2(g)
    - NIST-800-53-AU-3
    - NIST-800-53-AC-17(1)
    - NIST-800-53-AU-1(b)
    - NIST-800-53-AU-10
    - NIST-800-53-AU-12(a)
    - NIST-800-53-AU-12(c)
    - NIST-800-53-AU-14(1)
    - NIST-800-53-IR-5
    - CJIS-5.4.1.1

Rule   install the auditd service   [ref]

The auditd service should be installed.

Rationale:

The auditd service is an access monitoring and accounting daemon, watching system calls to audit any access, in comparision with potential local access control policy such as SELinux policy.

Severity: 
medium
Identifiers and References

References:  NT28(R50)

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
- name: Ensure auditd is installed
  package:
    name: auditd
    state: present
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - package_auditd_installed
    - medium_severity
    - enable_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
Remediation Puppet snippet:   (show)

Complexity:low
Disruption:low
Strategy:enable
include install_auditd

class install_auditd {
  package { 'auditd':
    ensure => 'installed',
  }
}
Group   File Permissions and Masks   Group contains 5 groups and 17 rules

[ref]   Traditional Unix security relies heavily on file and directory permissions to prevent unauthorized users from reading or modifying files to which they should not have access.

Several of the commands in this section search filesystems for files or directories with certain characteristics, and are intended to be run on every local partition on a given system. When the variable PART appears in one of the commands below, it means that the command is intended to be run repeatedly, with the name of each local partition substituted for PART in turn.

The following command prints a list of all xfs partitions on the local system, which is the default filesystem for Debian 8 installations:

$ mount -t xfs | awk '{print $3}'
For any systems that use a different local filesystem type, modify this command as appropriate.

Group   Verify Permissions on Important Files and Directories   Group contains 1 group and 15 rules

[ref]   Permissions for many files on a system must be set restrictively to ensure sensitive information is properly protected. This section discusses important permission restrictions which can be verified to ensure that no harmful discrepancies have arisen.

Group   Verify Permissions on Files with Local Account Information and Credentials   Group contains 12 rules

Rule   Verify Permissions on shadow File   [ref]

To properly set the permissions of /etc/shadow, run the command:

$ sudo chmod 0640 /etc/shadow

Rationale:

The /etc/shadow file contains the list of local system accounts and stores password hashes. Protection of this file is critical for system security. Failure to give ownership of this file to root provides the designated owner with access to sensitive information which could weaken the system security posture.

Severity: 
medium
Identifiers and References

References:  NT28(R36), 6.1.3, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2.2, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5, Req-8.7.c

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chmod 0640 /etc/shadow
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/shadow
  stat:
    path: /etc/shadow
  register: file_exists
  tags:
    - file_permissions_etc_shadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

- name: Ensure permission 0640 on /etc/shadow
  file:
    path: /etc/shadow
    mode: 416
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_permissions_etc_shadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

Rule   Verify User Who Owns shadow File   [ref]

To properly set the owner of /etc/shadow, run the command:

$ sudo chown root /etc/shadow 

Rationale:

The /etc/shadow file contains the list of local system accounts and stores password hashes. Protection of this file is critical for system security. Failure to give ownership of this file to root provides the designated owner with access to sensitive information which could weaken the system security posture.

Severity: 
medium
Identifiers and References

References:  6.1.3, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2.2, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5, Req-8.7.c

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chown 0 /etc/shadow
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/shadow
  stat:
    path: /etc/shadow
  register: file_exists
  tags:
    - file_owner_etc_shadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

- name: Ensure owner 0 on /etc/shadow
  file:
    path: /etc/shadow
    owner: 0
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_owner_etc_shadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

Rule   Verify User Who Owns group File   [ref]

To properly set the owner of /etc/group, run the command:

$ sudo chown root /etc/group 

Rationale:

The /etc/group file contains information regarding groups that are configured on the system. Protection of this file is important for system security.

Severity: 
medium
Identifiers and References

References:  6.1.4, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2.2, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5, Req-8.7.c

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chown 0 /etc/group
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/group
  stat:
    path: /etc/group
  register: file_exists
  tags:
    - file_owner_etc_group
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

- name: Ensure owner 0 on /etc/group
  file:
    path: /etc/group
    owner: 0
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_owner_etc_group
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

Rule   Verify Permissions on group File   [ref]

To properly set the permissions of /etc/passwd, run the command:

$ sudo chmod 0644 /etc/passwd

Rationale:

The /etc/group file contains information regarding groups that are configured on the system. Protection of this file is important for system security.

Severity: 
medium
Identifiers and References

References:  6.1.4, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2.2, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5, Req-8.7.c

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chmod 0644 /etc/group
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/group
  stat:
    path: /etc/group
  register: file_exists
  tags:
    - file_permissions_etc_group
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

- name: Ensure permission 0644 on /etc/group
  file:
    path: /etc/group
    mode: 420
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_permissions_etc_group
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

Rule   Verify Group Who Owns gshadow File   [ref]

To properly set the group owner of /etc/gshadow, run the command:

$ sudo chgrp root /etc/gshadow

Rationale:

The /etc/gshadow file contains group password hashes. Protection of this file is critical for system security.

Severity: 
medium
Identifiers and References

References:  6.1.5, 12, 13, 14, 15, 16, 18, 3, 5, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chgrp 42 /etc/gshadow
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/gshadow
  stat:
    path: /etc/gshadow
  register: file_exists
  tags:
    - file_groupowner_etc_gshadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AC-6

- name: Ensure group owner 42 on /etc/gshadow
  file:
    path: /etc/gshadow
    group: 42
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_groupowner_etc_gshadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AC-6

Rule   Verify Group Who Owns passwd File   [ref]

To properly set the group owner of /etc/passwd, run the command:

$ sudo chgrp root /etc/passwd

Rationale:

The /etc/passwd file contains information about the users that are configured on the system. Protection of this file is critical for system security.

Severity: 
medium
Identifiers and References

References:  6.1.2, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2.2, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5, Req-8.7.c

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chgrp 0 /etc/passwd
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/passwd
  stat:
    path: /etc/passwd
  register: file_exists
  tags:
    - file_groupowner_etc_passwd
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

- name: Ensure group owner 0 on /etc/passwd
  file:
    path: /etc/passwd
    group: 0
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_groupowner_etc_passwd
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

Rule   Verify Group Who Owns shadow File   [ref]

To properly set the group owner of /etc/shadow, run the command:

$ sudo chgrp root /etc/shadow

Rationale:

The /etc/shadow file stores password hashes. Protection of this file is critical for system security.

Severity: 
medium
Identifiers and References

References:  6.1.3, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2.2, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5, Req-8.7.c

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chgrp 42 /etc/shadow
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/shadow
  stat:
    path: /etc/shadow
  register: file_exists
  tags:
    - file_groupowner_etc_shadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

- name: Ensure group owner 42 on /etc/shadow
  file:
    path: /etc/shadow
    group: 42
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_groupowner_etc_shadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

Rule   Verify User Who Owns gshadow File   [ref]

To properly set the owner of /etc/gshadow, run the command:

$ sudo chown root /etc/gshadow 

Rationale:

The /etc/gshadow file contains group password hashes. Protection of this file is critical for system security.

Severity: 
medium
Identifiers and References

References:  6.1.5, 12, 13, 14, 15, 16, 18, 3, 5, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chown 0 /etc/gshadow
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/gshadow
  stat:
    path: /etc/gshadow
  register: file_exists
  tags:
    - file_owner_etc_gshadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AC-6

- name: Ensure owner 0 on /etc/gshadow
  file:
    path: /etc/gshadow
    owner: 0
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_owner_etc_gshadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AC-6

Rule   Verify Group Who Owns group File   [ref]

To properly set the group owner of /etc/group, run the command:

$ sudo chgrp root /etc/group

Rationale:

The /etc/group file contains information regarding groups that are configured on the system. Protection of this file is important for system security.

Severity: 
medium
Identifiers and References

References:  6.1.4, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2.2, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5, Req-8.7.c

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chgrp 0 /etc/group
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/group
  stat:
    path: /etc/group
  register: file_exists
  tags:
    - file_groupowner_etc_group
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

- name: Ensure group owner 0 on /etc/group
  file:
    path: /etc/group
    group: 0
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_groupowner_etc_group
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

Rule   Verify Permissions on gshadow File   [ref]

To properly set the permissions of /etc/gshadow, run the command:

$ sudo chmod 0000 /etc/gshadow

Rationale:

The /etc/gshadow file contains group password hashes. Protection of this file is critical for system security.

Severity: 
medium
Identifiers and References

References:  NT28(R36), 6.1.5, 12, 13, 14, 15, 16, 18, 3, 5, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chmod 0640 /etc/gshadow
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/gshadow
  stat:
    path: /etc/gshadow
  register: file_exists
  tags:
    - file_permissions_etc_gshadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AC-6

- name: Ensure permission 0640 on /etc/gshadow
  file:
    path: /etc/gshadow
    mode: 416
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_permissions_etc_gshadow
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - NIST-800-53-AC-6

Rule   Verify User Who Owns passwd File   [ref]

To properly set the owner of /etc/passwd, run the command:

$ sudo chown root /etc/passwd 

Rationale:

The /etc/passwd file contains information about the users that are configured on the system. Protection of this file is critical for system security.

Severity: 
medium
Identifiers and References

References:  6.1.2, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2.2, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5, Req-8.7.c

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chown 0 /etc/passwd
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/passwd
  stat:
    path: /etc/passwd
  register: file_exists
  tags:
    - file_owner_etc_passwd
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

- name: Ensure owner 0 on /etc/passwd
  file:
    path: /etc/passwd
    owner: 0
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_owner_etc_passwd
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

Rule   Verify Permissions on passwd File   [ref]

To properly set the permissions of /etc/passwd, run the command:

$ sudo chmod 0644 /etc/passwd

Rationale:

If the /etc/passwd file is writable by a group-owner or the world the risk of its compromise is increased. The file contains the list of accounts on the system and associated information, and protection of this file is critical for system security.

Severity: 
medium
Identifiers and References

References:  6.1.2, 12, 13, 14, 15, 16, 18, 3, 5, 5.5.2.2, APO01.06, DSS05.04, DSS05.07, DSS06.02, 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, AC-6, PR.AC-4, PR.DS-5, Req-8.7.c

Remediation Shell script:   (show)

Complexity:low
Disruption:low
Strategy:configure

chmod 0644 /etc/passwd
Remediation Ansible snippet:   (show)

Complexity:low
Disruption:low
Strategy:configure
- name: Test for existence /etc/passwd
  stat:
    path: /etc/passwd
  register: file_exists
  tags:
    - file_permissions_etc_passwd
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

- name: Ensure permission 0644 on /etc/passwd
  file:
    path: /etc/passwd
    mode: 420
  when: file_exists.stat is defined and file_exists.stat.exists
  tags:
    - file_permissions_etc_passwd
    - medium_severity
    - configure_strategy
    - low_complexity
    - low_disruption
    - no_reboot_needed
    - PCI-DSS-Req-8.7.c
    - NIST-800-53-AC-6
    - CJIS-5.5.2.2

Rule   Verify that local System.map file (if exists) is readable only by root   [ref]

Files containing sensitive informations should be protected by restrictive permissions. Most of the time, there is no need that these files need to be read by any non-root user To properly set the permissions of /boot/System.map-*, run the command:

$ sudo chmod 0600 /boot/System.map-*

Rationale:

The System.map file contains information about kernel symbols and can give some hints to generate local exploitation.

Severity: 
unknown
Identifiers and References

References:  NT28(R13)

Group   Restrict Programs from Dangerous Execution Patterns   Group contains 2 groups and 2 rules

[ref]   The recommendations in this section are designed to ensure that the system's features to protect against potentially dangerous program execution are activated. These protections are applied at the system initialization or kernel level, and defend against certain types of badly-configured or compromised programs.

Group   Disable Core Dumps   Group contains 1 rule

[ref]   A core dump file is the memory image of an executable program when it was terminated by the operating system due to errant behavior. In most cases, only software developers legitimately need to access these files. The core dump files may also contain sensitive information, or unnecessarily occupy large amounts of disk space.

Once a hard limit is set in /etc/security/limits.conf, a user cannot increase that limit within his or her own session. If access to core dumps is required, consider restricting them to only certain users or groups. See the limits.conf man page for more information.

The core dumps of setuid programs are further protected. The sysctl variable fs.suid_dumpable controls whether the kernel allows core dumps from these programs at all. The default value of 0 is recommended.

Rule   Disable Core Dumps for SUID programs   [ref]

To set the runtime status of the fs.suid_dumpable kernel parameter, run the following command:

$ sudo sysctl -w fs.suid_dumpable=0
If this is not the system default value, add the following line to a file in the directory /etc/sysctl.d:
fs.suid_dumpable = 0

Rationale:

The core dump of a setuid program is more likely to contain sensitive data, as the program itself runs with greater privileges than the user who initiated execution of the program. Disabling the ability for any setuid program to write a core file decreases the risk of unauthorized access of such data.

Severity: 
medium
Identifiers and References

References:  1.5.1, 164.308(a)(1)(ii)(D), 164.308(a)(3), 164.308(a)(4), 164.310(b), 164.310(c), 164.312(a), 164.312(e), SI-11

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:medium
Reboot:true
Strategy:disable
- name: Ensure sysctl fs.suid_dumpable is set to 0
  sysctl:
    name: fs.suid_dumpable
    value: 0
    state: present
    reload: true
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - sysctl_fs_suid_dumpable
    - medium_severity
    - disable_strategy
    - low_complexity
    - medium_disruption
    - reboot_required
    - NIST-800-53-SI-11
Group   Enable ExecShield   Group contains 1 rule

[ref]   ExecShield describes kernel features that provide protection against exploitation of memory corruption errors such as buffer overflows. These features include random placement of the stack and other memory regions, prevention of execution in memory that should only hold data, and special handling of text buffers. These protections are enabled by default on 32-bit systems and controlled through sysctl variables kernel.exec-shield and kernel.randomize_va_space. On the latest 64-bit systems, kernel.exec-shield cannot be enabled or disabled with sysctl.

Rule   Enable Randomized Layout of Virtual Address Space   [ref]

To set the runtime status of the kernel.randomize_va_space kernel parameter, run the following command:

$ sudo sysctl -w kernel.randomize_va_space=2
If this is not the system default value, add the following line to a file in the directory /etc/sysctl.d:
kernel.randomize_va_space = 2

Rationale:

Address space layout randomization (ASLR) makes it more difficult for an attacker to predict the location of attack code they have introduced into a process's address space during an attempt at exploitation. Additionally, ASLR makes it more difficult for an attacker to know the location of existing code in order to re-purpose it using return oriented programming (ROP) techniques.

Severity: 
medium
Identifiers and References

References:  1.5.1, 3.1.7, CCI-000366, 164.308(a)(1)(ii)(D), 164.308(a)(3), 164.308(a)(4), 164.310(b), 164.310(c), 164.312(a), 164.312(e), SC-30(2), SC-39, SRG-OS-000480-GPOS-00227, 040201

Remediation Ansible snippet:   (show)

Complexity:low
Disruption:medium
Reboot:true
Strategy:disable
- name: Ensure sysctl kernel.randomize_va_space is set to 2
  sysctl:
    name: kernel.randomize_va_space
    value: 2
    state: present
    reload: true
  when: ansible_virtualization_role != "guest" or ansible_virtualization_type != "docker"
  tags:
    - sysctl_kernel_randomize_va_space
    - medium_severity
    - disable_strategy
    - low_complexity
    - medium_disruption
    - reboot_required
    - NIST-800-171-3.1.7
    - NIST-800-53-SC-30(2)
    - NIST-800-53-SC-39
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