Guide to the Secure Configuration of Red Hat Enterprise Linux 6
https://www.open-scap.org/security-policies/scap-security-guide
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.
This benchmark is a direct port of a SCAP Security Guide benchmark developed for Red Hat Enterprise Linux. It has been modified through an automated process to remove specific dependencies on Red Hat Enterprise Linux and to function with CentOS. The result is a generally useful SCAP Security Guide benchmark with the following caveats:
- CentOS is not an exact copy of Red Hat Enterprise Linux. There may be configuration differences that produce false positives and/or false negatives. If this occurs please file a bug report.
- CentOS has its own build system, compiler options, patchsets, and is a community supported, non-commercial operating system. CentOS does not inherit certifications or evaluations from Red Hat Enterprise Linux. As such, some configuration rules (such as those requiring FIPS 140-2 encryption) will continue to fail on CentOS.
Members of the CentOS community are invited to participate in OpenSCAP and SCAP Security Guide development. Bug reports and patches can be sent to GitHub: https://github.com/OpenSCAP/scap-security-guide. The mailing list is at https://fedorahosted.org/mailman/listinfo/scap-security-guide.
Profile Information
| Profile ID | (default) |
|---|
CPE Platforms
- cpe:/o:redhat:enterprise_linux:6
- cpe:/o:centos:centos:6
- cpe:/o:redhat:enterprise_linux:6::client
- cpe:/o:redhat:enterprise_linux:6::computenode
Revision History
Current version: 0.1.44
- draft (as of 2019-05-06)
Table of Contents
- Remediation functions used by the SCAP Security Guide Project
- Services
- FTP Server
- Avahi Server
- X Window System
- Deprecated services
- Print Support
- Base Services
- Obsolete Services
- SNMP Server
- LDAP
- DHCP
- Web Server
- Docker Service
- Proxy Server
- IMAP and POP3 Server
- Mail Server Software
- Cron and At Daemons
- System Security Services Daemon
- APT service configuration
- Network Routing
- SSH Server
- DNS Server
- NFS and RPC
- Network Time Protocol
- Samba(SMB) Microsoft Windows File Sharing Server
- System Settings
- Configure Syslog
- Protect Random-Number Entropy Pool
- Network Configuration and Firewalls
- File Permissions and Masks
- System Accounting with auditd
- Set Boot Loader Password
- SELinux
- Installing and Maintaining Software
- Set Boot Loader Password
- Account and Access Control
- Introduction
Checklist
| Group Guide to the Secure Configuration of Red Hat Enterprise Linux 6 | |
| Group Remediation functions used by the SCAP Security Guide Project | |
[ref] XCCDF form of the various remediation functions as used by remediation scripts from the SCAP Security Guide Project. | |
| Group Services | |
[ref]
The best protection against vulnerable software is running less software. This section describes how to review
the software which Red Hat Enterprise Linux 6 installs on a system and disable software which is not needed. It
then enumerates the software packages installed on a default Red Hat Enterprise Linux 6 system and provides guidance about which
ones can be safely disabled.
| |
| Group FTP Server | |
[ref]
FTP is a common method for allowing remote access to
files. Like telnet, the FTP protocol is unencrypted, which means
that passwords and other data transmitted during the session can be
captured and that the session is vulnerable to hijacking.
Therefore, running the FTP server software is not recommended.
| |
| Group Configure vsftpd to Provide FTP Service if Necessary | |
[ref]
The primary vsftpd configuration file is
| |
| Group Restrict the Set of Users Allowed to Access FTP | |
[ref] This section describes how to disable non-anonymous (password-based) FTP logins, or, if it is not possible to do this entirely due to legacy applications, how to restrict insecure FTP login to only those users who have an identified need for this access. | |
| Group Use vsftpd to Provide FTP Service if Necessary | |
[ref] If your use-case requires FTP service, install and set-up vsftpd to provide it. | |
| Group Disable vsftpd if Possible | |
[ref] To minimize attack surface, disable vsftpd if at all possible. | |
| Group Avahi Server | |
[ref] The Avahi daemon implements the DNS Service Discovery and Multicast DNS protocols, which provide service and host discovery on a network. It allows a system to automatically identify resources on the network, such as printers or web servers. This capability is also known as mDNSresponder and is a major part of Zeroconf networking. | |
| Group Configure Avahi if Necessary | |
[ref]
If your system requires the Avahi daemon, its configuration can be restricted
to improve security. The Avahi daemon configuration file is
| |
| Group Disable Avahi Server if Possible | |
[ref] Because the Avahi daemon service keeps an open network port, it is subject to network attacks. Disabling it can reduce the system's vulnerability to such attacks. | |
| Group X Window System | |
[ref] The X Window System implementation included with the system is called X.org. | |
| Group Disable X Windows | |
[ref] Unless there is a mission-critical reason for the system to run a graphical user interface, ensure X is not set to start automatically at boot and remove the X Windows software packages. There is usually no reason to run X Windows on a dedicated server system, as it increases the system's attack surface and consumes system resources. Administrators of server systems should instead login via SSH or on the text console. | |
| Group Deprecated services | |
[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. | |
| Group Print Support | |
[ref]
The Common Unix Printing System (CUPS) service provides both local
and network printing support. A system running the CUPS service can accept
print jobs from other systems, process them, and send them to the appropriate
printer. It also provides an interface for remote administration through a web
browser. The CUPS service is installed and activated by default. The project
homepage and more detailed documentation are available at
http://www.cups.org.
| |
| Group Configure the CUPS Service if Necessary | |
[ref] CUPS provides the ability to easily share local printers with other systems over the network. It does this by allowing systems to share lists of available printers. Additionally, each system that runs the CUPS service can potentially act as a print server. Whenever possible, the printer sharing and print server capabilities of CUPS should be limited or disabled. The following recommendations should demonstrate how to do just that. | |
| Group Base Services | |
[ref] This section addresses the base services that are installed on a Red Hat Enterprise Linux 6 default installation which are not covered in other sections. Some of these services listen on the network and should be treated with particular discretion. Other services are local system utilities that may or may not be extraneous. In general, system services should be disabled if not required. | |
| Group Obsolete Services | |
[ref]
This section discusses a number of network-visible
services which have historically caused problems for system
security, and for which disabling or severely limiting the service
has been the best available guidance for some time. As a result of
this, many of these services are not installed as part of Red Hat Enterprise Linux 6
by default.
| |
| Group Rlogin, Rsh, and Rexec | |
[ref] The Berkeley r-commands are legacy services which allow cleartext remote access and have an insecure trust model. | |
| Group Telnet | |
[ref] The telnet protocol does not provide confidentiality or integrity for information transmitted on the network. This includes authentication information such as passwords. Organizations which use telnet should be actively working to migrate to a more secure protocol. | |
| Group Chat/Messaging Services | |
[ref] The talk software makes it possible for users to send and receive messages across systems through a terminal session. | |
| Group NIS | |
[ref] The Network Information Service (NIS), also known as 'Yellow Pages' (YP), and its successor NIS+ have been made obsolete by Kerberos, LDAP, and other modern centralized authentication services. NIS should not be used because it suffers from security problems inherent in its design, such as inadequate protection of important authentication information. | |
| Group TFTP Server | |
[ref] TFTP is a lightweight version of the FTP protocol which has traditionally been used to configure networking equipment. However, TFTP provides little security, and modern versions of networking operating systems frequently support configuration via SSH or other more secure protocols. A TFTP server should be run only if no more secure method of supporting existing equipment can be found. | |
| Group Xinetd | |
[ref]
The | |
| Group SNMP Server | |
[ref] The Simple Network Management Protocol allows administrators to monitor the state of network devices, including computers. Older versions of SNMP were well-known for weak security, such as plaintext transmission of the community string (used for authentication) and usage of easily-guessable choices for the community string. | |
| Group Disable SNMP Server if Possible | |
[ref] The system includes an SNMP daemon that allows for its remote monitoring, though it not installed by default. If it was installed and activated but is not needed, the software should be disabled and removed. | |
| Group Configure SNMP Server if Necessary | |
[ref] If it is necessary to run the snmpd agent on the system, some best practices should be followed to minimize the security risk from the installation. The multiple security models implemented by SNMP cannot be fully covered here so only the following general configuration advice can be offered:
| |
| Group LDAP | |
[ref] LDAP is a popular directory service, that is, a standardized way of looking up information from a central database. Red Hat Enterprise Linux 6 includes software that enables a system to act as both an LDAP client and server. | |
| Group Configure OpenLDAP Server | |
[ref] This section details some security-relevant settings for an OpenLDAP server. Installation and configuration of OpenLDAP on Red Hat Enterprise Linux 6 is available at: https://access.redhat.com/site/documentation/en-US/Red_Hat_Enterprise_Linux/6/html/Deployment_Guide/ch-Directory_Servers.html. | |
| Group Install and Protect LDAP Certificate Files | |
[ref] Create the PKI directory for LDAP certificates if it does not already exist: $ sudo mkdir /etc/pki/tls/ldap $ sudo chown root:root /etc/pki/tls/ldap $ sudo chmod 755 /etc/pki/tls/ldapUsing removable media or some other secure transmission format, install the certificate files onto the LDAP server:
$ sudo chown root:ldap /etc/pki/tls/ldap/serverkey.pem $ sudo chown root:ldap /etc/pki/tls/ldap/servercert.pem $ sudo chmod 640 /etc/pki/tls/ldap/serverkey.pem $ sudo chmod 640 /etc/pki/tls/ldap/servercert.pemVerify that the CA's public certificate file has been installed as /etc/pki/tls/CA/cacert.pem, and has the correct permissions:
$ sudo mkdir /etc/pki/tls/CA $ sudo chown root:root /etc/pki/tls/CA/cacert.pem $ sudo chmod 644 /etc/pki/tls/CA/cacert.pemAs a result of these steps, the LDAP server will have access to its own private certificate and the key with which that certificate is encrypted, and to the public certificate file belonging to the CA. Note that it would be possible for the key to be protected further, so that processes running as ldap could not read it. If this were done, the LDAP server process would need to be restarted manually whenever the server rebooted. | |
| Group Configure OpenLDAP Clients | |
[ref]
This section provides information on which security settings are
important to configure in OpenLDAP clients by manually editing the appropriate
configuration files. Red Hat Enterprise Linux 6 provides an automated configuration tool called
authconfig and a graphical wrapper for authconfig called
Warning:
Before configuring any system to be an
LDAP client, ensure that a working LDAP server is present on the
network. | |
| Group DHCP | |
[ref]
The Dynamic Host Configuration Protocol (DHCP) allows
systems to request and obtain an IP address and other configuration
parameters from a server.
| |
| Group Disable DHCP Server | |
[ref]
The DHCP server | |
| Group Configure DHCP Server | |
[ref]
If the system must act as a DHCP server, the configuration
information it serves should be minimized. Also, support for other protocols
and DNS-updating schemes should be explicitly disabled unless needed. The
configuration file for dhcpd is called | |
| Group Disable DHCP Client | |
[ref] DHCP is the default network configuration method provided by the system installer, and common on many networks. Nevertheless, manual management of IP addresses for systems implies a greater degree of management and accountability for network activity. | |
| Group Configure DHCP Client if Necessary | |
[ref]
If DHCP must be used, then certain configuration changes can
minimize the amount of information it receives and applies from the network,
and thus the amount of incorrect information a rogue DHCP server could
successfully distribute. For more information on configuring dhclient, see the
| |
| Group Web Server | |
[ref]
The web server is responsible for providing access to
content via the HTTP protocol. Web servers represent a significant
security risk because:
The system's default web server software is Apache 2 and is provided in the RPM package httpd. | |
| Group Install Apache if Necessary | |
[ref]
If $ sudo yum install httpdThis method of installation is recommended over installing the "Web Server" package group during the system installation process. The Web Server package group includes many packages which are likely extraneous, while the command-line method installs only the required httpd package itself. | |
| Group Confirm Minimal Built-in Modules Installed | |
[ref]
The default $ httpd -lIf the number of compiled-in modules is significantly larger than the aforementioned set, this guide recommends re-installing httpd with a
reduced configuration. Minimizing the number of modules that are compiled into
the httpd binary, reduces risk by limiting the capabilities allowed by
the webserver. | |
| Group Secure Apache Configuration | |
[ref]
The | |
| Group Configure PHP Securely | |
[ref]
PHP is a widely-used and often misconfigured server-side scripting language. It should
be used with caution, but configured appropriately when needed.
# Do not expose PHP error messages to external users display_errors = Off # Enable safe mode safe_mode = On # Only allow access to executables in isolated directory safe_mode_exec_dir = php-required-executables-path # Limit external access to PHP environment safe_mode_allowed_env_vars = PHP_ # Restrict PHP information leakage expose_php = Off # Log all errors log_errors = On # Do not register globals for input data register_globals = Off # Minimize allowable PHP post size post_max_size = 1K # Ensure PHP redirects appropriately cgi.force_redirect = 0 # Disallow uploading unless necessary file_uploads = Off # Disallow treatment of file requests as fopen calls allow_url_fopen = Off # Enable SQL safe mode sql.safe_mode = On | |
| Group Configure Operating System to Protect Web Server | |
[ref] The following configuration steps should be taken on the system which hosts the web server, in order to provide as safe an environment as possible for the web server. | |
| Group Restrict File and Directory Access | |
[ref]
Minimize access to critical | |
| Group Run httpd in a chroot Jail if Practical | |
[ref]
Running ChrootDir /chroot/apacheThis necessitates placing all files required by httpd inside
/chroot/apache , including httpd's binaries, modules,
configuration files, and served web pages. The details of this configuration
are beyond the scope of this guide. This may also require additional SELinux
configuration. | |
| Group Configure HTTPD-Served Web Content Securely | |
[ref]
Running ChrootDir /chroot/apacheThis necessitates placing all files required by httpd inside
/chroot/apache , including httpd's binaries, modules,
configuration files, and served web pages. The details of this configuration
are beyond the scope of this guide. This may also require additional SELinux
configuration. | |
| Group Directory Restrictions | |
[ref] The Directory tags in the web server configuration file allow finer grained access control for a specified directory. All web directories should be configured on a case-by-case basis, allowing access only where needed. | |
| Group Use Denial-of-Service Protection Modules | |
[ref] Denial-of-service attacks are difficult to detect and prevent while maintaining acceptable access to authorized users. However, some traffic-shaping modules can be used to address the problem. Well-known DoS protection modules include: mod_cband mod_bwshare mod_limitipconn mod_evasiveDenial-of-service prevention should be implemented for a web server if such a threat exists. However, specific configuration details are very dependent on the environment and often best left at the discretion of the administrator. | |
| Group Restrict Web Server Information Leakage | |
[ref]
The | |
| Group Use Appropriate Modules to Improve httpd's Security | |
[ref]
Among the modules available for | |
| Group Deploy mod_security | |
[ref]
The | |
| Group Deploy mod_ssl | |
[ref]
Because HTTP is a plain text protocol, all traffic is susceptible to passive
monitoring. If there is a need for confidentiality, SSL should be configured
and enabled to encrypt content.
| |
| Group Configure PERL Securely | |
[ref] PERL (Practical Extraction and Report Language) is an interpreted language optimized for scanning arbitrary text files, extracting information from those text files, and printing reports based on that information. The language is often used in shell scripting and is intended to be practical, easy to use, and efficient means of generating interactive web pages for the user. | |
| Group Minimize Web Server Loadable Modules | |
[ref]
A default installation of $ sudo service httpd configtestThe purpose of each of the modules loaded by default will now be addressed one at a time. If none of a module's directives are being used, remove it. | |
| Group httpd Core Modules | |
[ref]
These modules comprise a basic subset of modules that are likely needed for base LoadModule auth_basic_module modules/mod_auth_basic.so LoadModule authn_default_module modules/mod_authn_default.so LoadModule authz_host_module modules/mod_authz_host.so LoadModule authz_user_module modules/mod_authz_user.so LoadModule authz_groupfile_module modules/mod_authz_groupfile.so LoadModule authz_default_module modules/mod_authz_default.so LoadModule log_config_module modules/mod_log_config.so LoadModule logio_module modules/mod_logio.so LoadModule setenvif_module modules/mod_setenvif.so LoadModule mime_module modules/mod_mome.so LoadModule autoindex_module modules/mod_autoindex.so LoadModule negotiation_module modules/mod_negotiation.so LoadModule dir_module modules/mod_dir.so LoadModule alias_module modules/mod_alias.soMinimizing the number of loadable modules available to the web server reduces risk by limiting the capabilities allowed by the web server. | |
| Group Minimize Modules for HTTP Basic Authentication | |
[ref]
The following modules are necessary if this web server will provide content that will
be restricted by a password.
LoadModule authn_file_module modules/mod_authn_file.so LoadModule authn_dbm_module modules/mod_authn_dbm.so authn_alias allows for authentication based on aliases. authn_anon
allows anonymous authentication similar to that of anonymous ftp sites. authz_owner
allows authorization based on file ownership. authz_dbm allows for authorization
based on group membership if the web server is using DBM authentication.
If the above functionality is unnecessary, comment out the related module: #LoadModule authn_alias_module modules/mod_authn_alias.so #LoadModule authn_anon_module modules/mod_authn_anon.so #LoadModule authz_owner_module modules/mod_authz_owner.so #LoadModule authz_dbm_module modules/mod_authz_dbm.so | |
| Group Minimize Various Optional Components | |
[ref] The following modules perform very specific tasks, sometimes providing access to just a few additional directives. If such functionality is not required (or if you are not using these directives), comment out the associated module:
| |
| Group Minimize Configuration Files Included | |
[ref]
The #Include conf.d/*.confIf the above change was made, ensure that the SSL encryption remains loaded by explicitly including the corresponding configuration file: Include conf.d/ssl.confIf PHP is necessary, a similar alteration must be made: Include conf.d/php.confExplicitly listing the configuration files to be loaded during web server start-up avoids the possibility of unwanted or malicious configuration files to be automatically included as part of the server's running configuration. | |
| Group Disable Apache if Possible | |
[ref] If Apache was installed and activated, but the system does not need to act as a web server, then it should be disabled and removed from the system. | |
| Group Docker Service | |
[ref] The docker service is necessary to create containers, which are self-sufficient and self-contained applications using the resource isolation features of the kernel. | |
| Group Proxy Server | |
[ref] A proxy server is a very desirable target for a potential adversary because much (or all) sensitive data for a given infrastructure may flow through it. Therefore, if one is required, the system acting as a proxy server should be dedicated to that purpose alone and be stored in a physically secure location. The system's default proxy server software is Squid, and provided in an RPM package of the same name. | |
| Group Disable Squid if Possible | |
[ref] If Squid was installed and activated, but the system does not need to act as a proxy server, then it should be disabled and removed. | |
| Group IMAP and POP3 Server | |
[ref] Dovecot provides IMAP and POP3 services. It is not installed by default. The project page at http://www.dovecot.org contains more detailed information about Dovecot configuration. | |
| Group Configure Dovecot if Necessary | |
[ref] If the system will operate as an IMAP or POP3 server, the dovecot software should be configured securely by following the recommendations below. | |
| Group Support Only the Necessary Protocols | |
[ref]
Dovecot supports the IMAP and POP3 protocols, as well as
SSL-protected versions of those protocols. Configure the Dovecot server
to support only the protocols needed by your site. Edit protocols = PROTOCOLIf possible, require SSL protection for all transactions. The SSL protocol variants listen on alternate ports (995 instead of 110 for pop3s, and 993 instead of 143 for imaps), and require SSL-aware clients. An alternate approach is to listen on the standard port and require the client to use the STARTTLS command before authenticating. | |
| Group Allow IMAP Clients to Access the Server | |
[ref]
The default iptables configuration does not allow inbound access to any services.
This modification will allow remote hosts to initiate connections to the IMAP daemon,
while keeping all other ports on the server in their default protected state.
To configure -A INPUT -m state --state NEW -p tcp --dport 143 -j ACCEPT | |
| Group Enable SSL Support | |
[ref] SSL should be used to encrypt network traffic between the Dovecot server and its clients. Users must authenticate to the Dovecot server in order to read their mail, and passwords should never be transmitted in clear text. In addition, protecting mail as it is downloaded is a privacy measure, and clients may use SSL certificates to authenticate the server, preventing another system from impersonating the server. | |
| Group Disable Dovecot | |
[ref] If the system does not need to operate as an IMAP or POP3 server, the dovecot software should be disabled and removed. | |
| Group Mail Server Software | |
[ref]
Mail servers are used to send and receive email over the network.
Mail is a very common service, and Mail Transfer Agents (MTAs) are obvious
targets of network attack.
Ensure that systems are not running MTAs unnecessarily,
and configure needed MTAs as defensively as possible.
| |
| Group Configure Operating System to Protect Mail Server | |
[ref] The guidance in this section is appropriate for any host which is operating as a site MTA, whether the mail server runs using Sendmail, Postfix, or some other software. | |
| Group Configure SSL Certificates for Use with SMTP AUTH | |
[ref] If SMTP AUTH is to be used, the use of SSL to protect credentials in transit is strongly recommended. There are also configurations for which it may be desirable to encrypt all mail in transit from one MTA to another, though such configurations are beyond the scope of this guide. In either event, the steps for creating and installing an SSL certificate are independent of the MTA in use, and are described here. | |
| Group Ensure Security of Postfix SSL Certificate | |
[ref] Create the PKI directory for mail certificates, if it does not already exist: $ sudo mkdir /etc/pki/tls/mail $ sudo chown root:root /etc/pki/tls/mail $ sudo chmod 755 /etc/pki/tls/mailUsing removable media or some other secure transmission format, install the files generated in the previous step onto the mail server: /etc/pki/tls/mail/serverkey.pem: the private key mailserverkey.pem /etc/pki/tls/mail/servercert.pem: the certificate file mailservercert.pemVerify the ownership and permissions of these files: $ sudo chown root:root /etc/pki/tls/mail/serverkey.pem $ sudo chown root:root /etc/pki/tls/mail/servercert.pem $ sudo chmod 600 /etc/pki/tls/mail/serverkey.pem $ sudo chmod 644 /etc/pki/tls/mail/servercert.pemVerify that the CA's public certificate file has been installed as /etc/pki/tls/CA/cacert.pem, and has the
correct permissions:
$ sudo chown root:root /etc/pki/tls/CA/cacert.pem $ sudo chmod 644 /etc/pki/tls/CA/cacert.pem | |
| Group Configure Postfix if Necessary | |
[ref]
Postfix stores its configuration files in the directory
/etc/postfix by default. The primary configuration file is
| |
| Group Control Mail Relaying | |
[ref] Postfix's mail relay controls are implemented with the help of the smtpd recipient restrictions option, which controls the restrictions placed on the SMTP dialogue once the sender and recipient envelope addresses are known. The guidance in the following sections should be applied to all systems. If there are systems which must be allowed to relay mail, but which cannot be trusted to relay unconditionally, configure SMTP AUTH with SSL support. | |
| Group Enact SMTP Recipient Restrictions | |
[ref]
To configure Postfix to restrict addresses to which it
will send mail, see:
http://www.postfix.org/SMTPD_ACCESS_README.html#danger
| |
| Group Use TLS for SMTP AUTH | |
[ref] Postfix provides options to use TLS for certificate-based authentication and encrypted sessions. An encrypted session protects the information that is transmitted with SMTP mail or with SASL authentication. To configure Postfix to protect all SMTP AUTH transactions using TLS, see http://www.postfix.org/TLS_README.html. | |
| Group Require SMTP AUTH Before Relaying from Untrusted Clients | |
[ref] SMTP authentication allows remote clients to relay mail safely by requiring them to authenticate before submitting mail. Postfix's SMTP AUTH uses an authentication library called SASL, which is not part of Postfix itself. To enable the use of SASL authentication, see http://www.postfix.org/SASL_README.html | |
| Group Enact SMTP Relay Restrictions | |
[ref]
To configure Postfix to restrict addresses to which it
will send mail, see:
http://www.postfix.org/SMTPD_ACCESS_README.html#danger
| |
| Group Configure Trusted Networks and Hosts | |
[ref]
Edit
| |
| Group Configure Postfix Resource Usage to Limit Denial of Service Attacks | |
[ref]
Edit default_process_limit = 100 smtpd_client_connection_count_limit = 10 smtpd_client_connection_rate_limit = 30 queue_minfree = 20971520 header_size_limit = 51200 message_size_limit = 10485760 smtpd_recipient_limit = 100The values here are examples. Warning:
Note: The values given here are examples, and may
need to be modified for any particular site. By default, the Postfix anvil
process gathers mail receipt statistics. To get information about about what
connection rates are typical at your site, look in /var/log/maillog
for lines with the daemon name postfix/anvil. | |
| Group Configure SMTP For Mail Clients | |
[ref] This section discusses settings for Postfix in a submission-only e-mail configuration. | |
| Group Cron and At Daemons | |
[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. | |
| Group Restrict at and cron to Authorized Users if Necessary | |
[ref]
The
| |
| Group System Security Services Daemon | |
[ref]
The System Security Services Daemon (SSSD) is a system daemon that provides access
to different identity and authentication providers such as Red Hat's IdM, Microsoft's AD,
openLDAP, MIT Kerberos, etc. It uses a common framework that can provide caching and offline
support to systems utilizing SSSD. SSSD using caching to reduce load on authentication
servers permit offline authentication as well as store extended user data.
| |
| Group System Security Services Daemon (SSSD) - LDAP | |
[ref]
The System Security Services Daemon (SSSD) is a system daemon that provides access
to different identity and authentication providers such as Red Hat's IdM, Microsoft's AD,
openLDAP, MIT Kerberos, etc. It uses a common framework that can provide caching and offline
support to systems utilizing SSSD. SSSD using caching to reduce load on authentication
servers permit offline authentication as well as store extended user data.
| |
| Group APT service configuration | |
[ref] The apt service manage the package management and update of the whole system. Its configuration need to be properly defined to ensure efficient security updates, packages and repository authentication and proper lifecycle management. | |
| Group Network Routing | |
[ref] A router is a very desirable target for a potential adversary because they fulfill a variety of infrastructure networking roles such as access to network segments, gateways to other networks, filtering, etc. Therefore, if one is required, the system acting as a router should be dedicated to that purpose alone and be stored in a physically secure location. The system's default routing software is Quagga, and provided in an RPM package of the same name. | |
| Group Disable Quagga if Possible | |
[ref] If Quagga was installed and activated, but the system does not need to act as a router, then it should be disabled and removed. | |
| Group SSH Server | |
[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 | |
| Group Configure OpenSSH Server if Necessary | |
[ref]
If the system needs to act as an SSH server, then
certain changes should be made to the OpenSSH daemon configuration
file | |
| Group Strengthen Firewall Configuration if Possible | |
[ref]
If the SSH server is expected to only receive connections from
the local network, then strengthen the default firewall rule for the SSH service
to only accept connections from the appropriate network segment(s).
firewall-cmd --permanent --add-rich-rule='rule family="ip_protocol" source address="netwk/mask" service name="ssh" accept' | |
| Group DNS Server | |
[ref] Most organizations have an operational need to run at least one nameserver. However, there are many common attacks involving DNS server software, and this server software should be disabled on any system on which it is not needed. | |
| Group Protect DNS Data from Tampering or Attack | |
[ref] This section discusses DNS configuration options which make it more difficult for attackers to gain access to private DNS data or to modify DNS data. | |
| Group Run Separate DNS Servers for External and Internal Queries | |
[ref]
Is it possible to run external and internal nameservers on
separate systems? If so, follow the configuration guidance in this section. On
the external nameserver, edit options {
allow-query { any; };
recursion no;
...
};
zone "example.com " IN {
...
};
On the internal nameserver, edit /etc/named.conf. Add or correct the
following directives, where SUBNET is the numerical IP representation of your
organization in the form xxx.xxx.xxx.xxx/xx:
acl internal {
SUBNET ;
localhost;
};
options {
allow-query { internal; };
...
};
zone "internal.example.com " IN {
...
}; | |
| Group Use Views to Partition External and Internal Information | |
[ref]
If it is not possible to run external and internal nameservers on
separate physical systems, run BIND9 and simulate this feature using views.
Edit acl internal {
SUBNET ;
localhost;
};
view "internal-view" {
match-clients { internal; };
zone "." IN {
type hint;
file "db.cache";
};
zone "internal.example.com " IN {
...
};
};
view "external-view" {
match-clients { any; };
recursion no;
zone "example.com " IN {
...
};
};Warning:
As shown in the example, database files which are
required for recursion, such as the root hints file, must be available to any
clients which are allowed to make recursive queries. Under typical
circumstances, this includes only the internal clients which are allowed to use
this server as a general-purpose nameserver. | |
| Group Disable DNS Server | |
[ref] DNS software should be disabled on any systems which does not need to be a nameserver. Note that the BIND DNS server software is not installed on Red Hat Enterprise Linux 6 by default. The remainder of this section discusses secure configuration of systems which must be nameservers. | |
| Group Isolate DNS from Other Services | |
[ref] This section discusses mechanisms for preventing the DNS server from interfering with other services. This is done both to protect the remainder of the network should a nameserver be compromised, and to make direct attacks on nameservers more difficult. | |
| Group Run DNS Software on Dedicated Servers | |
[ref] Since DNS is a high-risk service which must frequently be made available to the entire Internet, it is strongly recommended that no other services be offered by systems which act as organizational DNS servers. | |
| Group Run DNS Software in a chroot Jail | |
[ref]
Install the $ sudo yum install bind-chrootPlace a valid named.conf file inside the chroot jail: $ sudo cp /etc/named.conf /var/named/chroot/etc/named.conf $ sudo chown root:root /var/named/chroot/etc/named.conf $ sudo chmod 644 /var/named/chroot/etc/named.confCreate and populate an appropriate zone directory within the jail, based on the options directive. If your named.conf includes:
options {
directory "/path/to/DIRNAME ";
...
}
then copy that directory and its contents from the original zone directory:
$ sudo cp -r /path/to/DIRNAME /var/named/chroot/DIRNAMEAdd or correct the following line within /etc/sysconfig/named:
ROOTDIR=/var/named/chroot Warning:
If you are running BIND in a chroot jail, then you
should use the jailed named.conf as the primary nameserver
configuration file. That is, when this guide recommends editing
/etc/named.conf, you should instead edit
/var/named/chroot/etc/named.conf. | |
| Group NFS and RPC | |
[ref] The Network File System is a popular distributed filesystem for the Unix environment, and is very widely deployed. This section discusses the circumstances under which it is possible to disable NFS and its dependencies, and then details steps which should be taken to secure NFS's configuration. This section is relevant to systems operating as NFS clients, as well as to those operating as NFS servers. | |
| Group Configure NFS Servers | |
[ref] The steps in this section are appropriate for systems which operate as NFS servers. | |
| Group Use Access Lists to Enforce Authorization Restrictions | |
[ref]
When configuring NFS exports, ensure that each export line in
| |
| Group Export Filesystems Read-Only if Possible | |
[ref]
If a filesystem is being exported so that users can view the files in a convenient
fashion, but there is no need for users to edit those files, exporting the filesystem read-only
removes an attack vector against the server. The default filesystem export mode is | |
| Group Configure the Exports File Restrictively | |
[ref]
Linux's NFS implementation uses the file /DIR host1(opt1,opt2) host2(opt3)where /DIR is a directory or filesystem to export, hostN is an IP address, netblock,
hostname, domain, or netgroup to which to export, and optN is an option. | |
| Group Configure NFS Clients | |
[ref] The steps in this section are appropriate for systems which operate as NFS clients. | |
| Group Mount Remote Filesystems with Restrictive Options | |
[ref]
Edit the file | |
| Group Disable NFS Server Daemons | |
[ref]
There is no need to run the NFS server daemons | |
| Group Disable All NFS Services if Possible | |
[ref] If there is not a reason for the system to operate as either an NFS client or an NFS server, follow all instructions in this section to disable subsystems required by NFS. Warning:
The steps in this section will prevent a system
from operating as either an NFS client or an NFS server. Only perform these
steps on systems which do not need NFS at all. | |
| Group Disable Services Used Only by NFS | |
[ref]
If NFS is not needed, disable the NFS client daemons nfslock, rpcgssd, and rpcidmapd.
| |
| Group Disable netfs if Possible | |
[ref] To determine if any network filesystems handled by netfs are currently mounted on the system execute the following command: $ mount -t nfs,nfs4,smbfs,cifs,ncpfsIf the command did not return any output then disable netfs. | |
| Group Configure All Systems which Use NFS | |
[ref] The steps in this section are appropriate for all systems which run NFS, whether they operate as clients or as servers. | |
| Group Make Each System a Client or a Server, not Both | |
[ref] If NFS must be used, it should be deployed in the simplest configuration possible to avoid maintainability problems which may lead to unnecessary security exposure. Due to the reliability and security problems caused by NFS (specially NFSv3 and NFSv2), it is not a good idea for systems which act as NFS servers to also mount filesystems via NFS. At the least, crossed mounts (the situation in which each of two servers mounts a filesystem from the other) should never be used. | |
| Group Configure NFS Services to Use Fixed Ports (NFSv3 and NFSv2) | |
[ref]
Firewalling should be done at each host and at the border
firewalls to protect the NFS daemons from remote access, since NFS servers
should never be accessible from outside the organization. However, by default
for NFSv3 and NFSv2, the RPC Bind service assigns each NFS service to a port
dynamically at service startup time. Dynamic ports cannot be protected by port
filtering firewalls such as | |
| Group Network Time Protocol | |
[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.
| |
| Group Samba(SMB) Microsoft Windows File Sharing Server | |
[ref]
When properly configured, the Samba service allows
Linux systems to provide file and print sharing to Microsoft
Windows systems. There are two software packages that provide
Samba support. The first, | |
| Group Configure Samba if Necessary | |
[ref]
All settings for the Samba daemon can be found in
| |
| Group Restrict Printer Sharing | |
[ref]
By default, Samba utilizes the CUPS printing service to enable
printer sharing with Microsoft Windows workstations. If there are no printers
on the local system, or if printer sharing with Microsoft Windows is not
required, disable the printer sharing capability by commenting out the
following lines, found in [global] load printers = yes cups options = raw [printers] comment = All Printers path = /usr/spool/samba browseable = no guest ok = no writable = no printable = yesThere may be other options present, but these are the only options enabled and uncommented by default. Removing the [printers] share should be enough
for most users. If the Samba printer sharing capability is needed, consider
disabling the Samba network browsing capability or restricting access to a
particular set of users or network addresses. Set the valid users
parameter to a small subset of users or restrict it to a particular group of
users with the shorthand @. Separate each user or group of users with
a space. For example, under the [printers] share:
[printers] valid users = user @printerusers | |
| Group Restrict SMB File Sharing to Configured Networks | |
[ref]
Only users with local user accounts will be able to log in to
Samba shares by default. Shares can be limited to particular users or network
addresses. Use the [share] hosts allow = 192.168.1. 127.0.0.1 valid users = userone usertwo @usergroupIt is also possible to limit read and write access to particular users with the read list and write list options, though the permissions set by the system itself will override these settings. Set the read only attribute for each share to ensure that global settings will not accidentally override the individual share settings. Then, as with the valid users directive, separate each user or group of users with a space: [share] read only = yes write list = userone usertwo @usergroup | |
| Group Disable Samba if Possible | |
[ref] Even after the Samba server package has been installed, it will remain disabled. Do not enable this service unless it is absolutely necessary to provide Microsoft Windows file and print sharing functionality. | |
| Group System Settings | |
[ref] Contains rules that check correct system settings. | |
| Group Configure Syslog | |
[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.
| |
| Group Configure rsyslogd to Accept Remote Messages If Acting as a Log Server | |
| Group Rsyslog Logs Sent To Remote Host | |
| Group Ensure Proper Configuration of Log Files | |
[ref]
The file *.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.logSee 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 | |
| Group Configure Logwatch on the Central Log Server | |
[ref]
Is this system the central log server? If so, edit the file | |
| Group Ensure All Logs are Rotated by logrotate | |
[ref]
Edit the file /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. | |
| Group Protect Random-Number Entropy Pool | |
[ref] The I/O operations of the Linux kernel block layer due to their inherently unpredictable execution times have been traditionally considered as a reliable source to contribute to random-number entropy pool of the Linux kernel. This has changed with introduction of solid-state storage devices (SSDs) though. | |
| Group Network Configuration and Firewalls | |
[ref]
Most systems must be connected to a network of some
sort, and this brings with it the substantial risk of network
attack. This section discusses the security impact of decisions
about networking which must be made when configuring a system.
| |
| Group IPSec Support | |
[ref] Support for Internet Protocol Security (IPsec) is provided in Red Hat Enterprise Linux 6 with openswan and Libreswan. | |
| Group Transport Layer Security Support | |
[ref]
Support for Transport Layer Security (TLS), and its predecessor, the Secure
Sockets Layer (SSL), is included in Red Hat Enterprise Linux in the OpenSSL software (RPM package
| |
| Group Kernel Parameters Which Affect Networking | |
[ref]
The | |
| Group Network Related Kernel Runtime Parameters for Hosts and Routers | |
[ref] Certain kernel parameters should be set for systems which are acting as either hosts or routers to improve the system's ability defend against certain types of IPv4 protocol attacks. | |
| Group Network Parameters for Hosts Only | |
[ref] If the system is not going to be used as a router, then setting certain kernel parameters ensure that the host will not perform routing of network traffic. | |
| Group Uncommon Network Protocols | |
[ref] The system includes support for several network protocols which are not commonly used. Although security vulnerabilities in kernel networking code are not frequently discovered, the consequences can be dramatic. Ensuring uncommon network protocols are disabled reduces the system's risk to attacks targeted at its implementation of those protocols. Warning:
Although these protocols are not commonly used, avoid disruption
in your network environment by ensuring they are not needed
prior to disabling them. | |
| Group iptables and ip6tables | |
[ref]
A host-based firewall called | |
| Group Inspect and Activate Default Rules | |
[ref]
View the currently-enforced $ sudo iptables -nL --line-numbersThe command is analogous for ip6tables.
If the firewall does not appear to be active (i.e., no rules appear), activate it and ensure that it starts at boot by issuing the following commands (and analogously for ip6tables):
$ sudo service iptables restartThe default iptables rules are: Chain INPUT (policy ACCEPT) num target prot opt source destination 1 ACCEPT all -- 0.0.0.0/0 0.0.0.0/0 state RELATED,ESTABLISHED 2 ACCEPT icmp -- 0.0.0.0/0 0.0.0.0/0 3 ACCEPT all -- 0.0.0.0/0 0.0.0.0/0 4 ACCEPT tcp -- 0.0.0.0/0 0.0.0.0/0 state NEW tcp dpt:22 5 REJECT all -- 0.0.0.0/0 0.0.0.0/0 reject-with icmp-host-prohibited Chain FORWARD (policy ACCEPT) num target prot opt source destination 1 REJECT all -- 0.0.0.0/0 0.0.0.0/0 reject-with icmp-host-prohibited Chain OUTPUT (policy ACCEPT) num target prot opt source destinationThe ip6tables default rules are essentially the same. | |
| Group Strengthen the Default Ruleset | |
[ref]
The default rules can be strengthened. The system
scripts that activate the firewall rules expect them to be defined
in the configuration files Warning:
The program system-config-securitylevel
allows additional services to penetrate the default firewall rules
and automatically adjusts /etc/sysconfig/iptables. This program
is only useful if the default ruleset meets your security
requirements. Otherwise, this program should not be used to make
changes to the firewall configuration because it re-writes the
saved configuration file. | |
| Group Log and Drop Packets with Suspicious Source Addresses | |
[ref]
Packets with non-routable source addresses should be rejected, as they may indicate spoofing. Because the
modified policy will reject non-matching packets, you only need to add these rules if you are interested in also
logging these spoofing or suspicious attempts before they are dropped. If you do choose to log various suspicious
traffic, add identical rules with a target of -A INPUT -s 10.0.0.0/8 -j LOG --log-prefix "IP DROP SPOOF A: " -A INPUT -s 172.16.0.0/12 -j LOG --log-prefix "IP DROP SPOOF B: " -A INPUT -s 192.168.0.0/16 -j LOG --log-prefix "IP DROP SPOOF C: " -A INPUT -s 224.0.0.0/4 -j LOG --log-prefix "IP DROP MULTICAST D: " -A INPUT -s 240.0.0.0/5 -j LOG --log-prefix "IP DROP SPOOF E: " -A INPUT -d 127.0.0.0/8 -j LOG --log-prefix "IP DROP LOOPBACK: "Similarly, you might wish to log packets containing some IPv6 reserved addresses if they are not expected on your network: -A INPUT -i eth0 -s ::1 -j LOG --log-prefix "IPv6 DROP LOOPBACK: " -A INPUT -s 2002:E000::/20 -j LOG --log-prefix "IPv6 6to4 TRAFFIC: " -A INPUT -s 2002:7F00::/24 -j LOG --log-prefix "IPv6 6to4 TRAFFIC: " -A INPUT -s 2002:0000::/24 -j LOG --log-prefix "IPv6 6to4 TRAFFIC: " -A INPUT -s 2002:FF00::/24 -j LOG --log-prefix "IPv6 6to4 TRAFFIC: " -A INPUT -s 2002:0A00::/24 -j LOG --log-prefix "IPv6 6to4 TRAFFIC: " -A INPUT -s 2002:AC10::/28 -j LOG --log-prefix "IPv6 6to4 TRAFFIC: " -A INPUT -s 2002:C0A8::/32 -j LOG --log-prefix "IPv6 6to4 TRAFFIC: "If you are not expecting to see site-local multicast or auto-tunneled traffic, you can log those: -A INPUT -s FF05::/16 -j LOG --log-prefix "IPv6 SITE-LOCAL MULTICAST: " -A INPUT -s ::0.0.0.0/96 -j LOG --log-prefix "IPv4 COMPATIBLE IPv6 ADDR: "If you wish to block multicasts to all link-local nodes (e.g. if you are not using router auto-configuration and do not plan to have any services that multicast to the entire local network), you can block the link-local all-nodes multicast address (before accepting incoming ICMPv6): -A INPUT -d FF02::1 -j LOG --log-prefix "Link-local All-Nodes Multicast: "However, if you're going to allow IPv4 compatible IPv6 addresses (of the form ::0.0.0.0/96), you should then consider logging the non-routable IPv4-compatible addresses: -A INPUT -s ::0.0.0.0/104 -j LOG --log-prefix "IP NON-ROUTABLE ADDR: " -A INPUT -s ::127.0.0.0/104 -j LOG --log-prefix "IP DROP LOOPBACK: " -A INPUT -s ::224.0.0.0.0/100 -j LOG --log-prefix "IP DROP MULTICAST D: " -A INPUT -s ::255.0.0.0/104 -j LOG --log-prefix "IP BROADCAST: "If you are not expecting to see any IPv4 (or IPv4-compatible) traffic on your network, consider logging it before it gets dropped: -A INPUT -s ::FFFF:0.0.0.0/96 -j LOG --log-prefix "IPv4 MAPPED IPv6 ADDR: " -A INPUT -s 2002::/16 -j LOG --log-prefix "IPv6 6to4 ADDR: "The following rule will log all traffic originating from a site-local address, which is deprecated address space: -A INPUT -s FEC0::/10 -j LOG --log-prefix "SITE-LOCAL ADDRESS TRAFFIC: " | |
| Group Restrict ICMP Message Types | |
[ref]
In -A INPUT -p icmp --icmp-type any -j ACCEPTand insert the lines: -A INPUT -p icmp --icmp-type echo-reply -j ACCEPT -A INPUT -p icmp --icmp-type destination-unreachable -j ACCEPT -A INPUT -p icmp --icmp-type time-exceeded -j ACCEPTTo allow the system to respond to pings, also insert the following line: -A INPUT -p icmp --icmp-type echo-request -j ACCEPTPing responses can also be limited to certain networks or hosts by using the -s option in the previous rule. Because IPv6 depends so heavily on ICMPv6, it is preferable to deny the ICMPv6 packets you know you don't need (e.g. ping requests) in /etc/sysconfig/ip6tables, while letting everything else
through:
-A INPUT -p icmpv6 --icmpv6-type echo-request -j DROPIf you are going to statically configure the system's address, it should ignore Router Advertisements which could add another IPv6 address to the interface or alter important network settings: -A INPUT -p icmpv6 --icmpv6-type router-advertisement -j DROPRestricting ICMPv6 message types in /etc/sysconfig/ip6tables is not
recommended because the operation of IPv6 depends heavily on ICMPv6. Thus, great
care must be taken if any other ICMPv6 types are blocked. | |
| Group firewalld | |
[ref]
The dynamic firewall daemon | |
| Group Strengthen the Default Ruleset | |
[ref]
The default rules can be strengthened. The system
scripts that activate the firewall rules expect them to be defined
in configuration files under the Warning:
The program firewall-config
allows additional services to penetrate the default firewall rules
and automatically adjusts the firewalld ruleset(s). | |
| Group Inspect and Activate Default firewalld Rules | |
[ref]
Firewalls can be used to separate networks into different zones
based on the level of trust the user has decided to place on the devices and
traffic within that network.
It is possible to designate one of these zones to be the default zone. When interface connections are added to NetworkManager, they are assigned
to the default zone. On installation, the default zone in firewalld is set to
be the public zone.
To find out all the settings of a zone, for example the public zone,
enter the following command as root:
# firewall-cmd --zone=public --list-allExample output of this command might look like the following: # firewall-cmd --zone=public --list-all public interfaces: services: mdns dhcpv6-client ssh ports: forward-ports: icmp-blocks: source-quenchTo view the network zones currently active, enter the following command as root: # firewall-cmd --get-serviceThe following listing displays the result of this command on common Red Hat Enterprise Linux 6 system: # firewall-cmd --get-service amanda-client bacula bacula-client dhcp dhcpv6 dhcpv6-client dns ftp high-availability http https imaps ipp ipp-client ipsec kerberos kpasswd ldap ldaps libvirt libvirt-tls mdns mountd ms-wbt mysql nfs ntp openvpn pmcd pmproxy pmwebapi pmwebapis pop3s postgresql proxy-dhcp radius rpc-bind samba samba-client smtp ssh telnet tftp tftp-client transmission-client vnc-server wbem-httpsFinally to view the network zones that will be active after the next firewalld service reload, enter the following command as root: # firewall-cmd --get-service --permanent | |
| Group IPv6 | |
[ref] The system includes support for Internet Protocol version 6. A major and often-mentioned improvement over IPv4 is its enormous increase in the number of available addresses. Another important feature is its support for automatic configuration of many network settings. | |
| Group Disable Support for IPv6 Unless Needed | |
[ref] Despite configuration that suggests support for IPv6 has been disabled, link-local IPv6 address auto-configuration occurs even when only an IPv4 address is assigned. The only way to effectively prevent execution of the IPv6 networking stack is to instruct the system not to activate the IPv6 kernel module. | |
| Group Configure IPv6 Settings if Necessary | |
[ref] A major feature of IPv6 is the extent to which systems implementing it can automatically configure their networking devices using information from the network. From a security perspective, manually configuring important configuration information is preferable to accepting it from the network in an unauthenticated fashion. | |
| Group Disable Automatic Configuration | |
[ref]
Disable the system's acceptance of router
advertisements and redirects by adding or correcting the following
line in IPV6_AUTOCONF=no | |
| Group Limit Network-Transmitted Configuration if Using Static IPv6 Addresses | |
[ref]
To limit the configuration information requested from other
systems and accepted from the network on a system that uses
statically-configured IPv6 addresses, add the following lines to
net.ipv6.conf.default.router_solicitations = 0 net.ipv6.conf.default.accept_ra_rtr_pref = 0 net.ipv6.conf.default.accept_ra_pinfo = 0 net.ipv6.conf.default.accept_ra_defrtr = 0 net.ipv6.conf.default.autoconf = 0 net.ipv6.conf.default.dad_transmits = 0 net.ipv6.conf.default.max_addresses = 1The router_solicitations setting determines how many router
solicitations are sent when bringing up the interface. If addresses are
statically assigned, there is no need to send any solicitations.
The accept_ra_pinfo setting controls whether the system will accept
prefix info from the router.
The accept_ra_defrtr setting controls whether the system will accept
Hop Limit settings from a router advertisement. Setting it to 0 prevents a
router from changing your default IPv6 Hop Limit for outgoing packets.
The autoconf setting controls whether router advertisements can cause
the system to assign a global unicast address to an interface.
The dad_transmits setting determines how many neighbor solicitations
to send out per address (global and link-local) when bringing up an interface
to ensure the desired address is unique on the network.
The max_addresses setting determines how many global unicast IPv6
addresses can be assigned to each interface. The default is 16, but it should
be set to exactly the number of statically configured global addresses
required. | |
| Group Disable Unused Interfaces | |
[ref]
Network interfaces expand the attack surface of the
system. Unused interfaces are not monitored or controlled, and
should be disabled.
$ sudo rm /etc/sysconfig/network-scripts/ifcfg-interfaceIf the system is a standalone machine with no need for network access or even communication over the loopback device, then disable this service. The network service can be disabled with the following command: $ sudo chkconfig network off | |
| Group Wireless Networking | |
[ref]
Wireless networking, such as 802.11
(WiFi) and Bluetooth, can present a security risk to sensitive or
classified systems and networks. Wireless networking hardware is
much more likely to be included in laptop or portable systems than
in desktops or servers.
| |
| Group Disable Wireless Through Software Configuration | |
[ref] If it is impossible to remove the wireless hardware from the device in question, disable as much of it as possible through software. The following methods can disable software support for wireless networking, but note that these methods do not prevent malicious software or careless users from re-activating the devices. | |
| Group File Permissions and Masks | |
[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.
$ mount -t xfs | awk '{print $3}'
For any systems that use a different
local filesystem type, modify this command as appropriate. | |
| Group Restrict Partition Mount Options | |
[ref]
System partitions can be mounted with certain options
that limit what files on those partitions can do. These options
are set in the | |
| Group Restrict Programs from Dangerous Execution Patterns | |
[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 Enable Execute Disable (XD) or No Execute (NX) Support on x86 Systems | |
[ref] Recent processors in the x86 family support the ability to prevent code execution on a per memory page basis. Generically and on AMD processors, this ability is called No Execute (NX), while on Intel processors it is called Execute Disable (XD). This ability can help prevent exploitation of buffer overflow vulnerabilities and should be activated whenever possible. Extra steps must be taken to ensure that this protection is enabled, particularly on 32-bit x86 systems. Other processors, such as Itanium and POWER, have included such support since inception and the standard kernel for those platforms supports the feature. This is enabled by default on the latest Red Hat and Fedora systems if supported by the hardware. | |
| Group Disable Core Dumps | |
[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.
| |
| Group Daemon Umask | |
[ref] The umask is a per-process setting which limits the default permissions for creation of new files and directories. The system includes initialization scripts which set the default umask for system daemons. | |
| Group Enable ExecShield | |
[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 | |
| Group Memory Poisoning | |
[ref] Memory Poisoning consists of writing a special value to uninitialized or freed memory. Poisoning can be used as a mechanism to prevent leak of information and detection of corrupted memory. | |
| Group Verify Permissions on Important Files and Directories | |
[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 File Permissions Within Some Important Directories | |
[ref] Some directories contain files whose confidentiality or integrity is notably important and may also be susceptible to misconfiguration over time, particularly if unpackaged software is installed. As such, an argument exists to verify that files' permissions within these directories remain configured correctly and restrictively. | |
| Group Verify Permissions on Files with Local Account Information and Credentials | |
[ref]
The default restrictive permissions for files which act as
important security databases such as | |
| Group Restrict Dynamic Mounting and Unmounting of Filesystems | |
[ref]
Linux includes a number of facilities for the automated addition
and removal of filesystems on a running system. These facilities may be
necessary in many environments, but this capability also carries some risk -- whether direct
risk from allowing users to introduce arbitrary filesystems,
or risk that software flaws in the automated mount facility itself could
allow an attacker to compromise the system.
$ find /lib/modules/`uname -r`/kernel/fs -type f -name '*.ko'If these filesystems are not required then they can be explicitly disabled in a configuratio file in /etc/modprobe.d. | |
| Group System Accounting with auditd | |
[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, ExecStartPost=-/sbin/augenrules --loadin 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.rulesin 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)
| |
| Group Configure auditd Data Retention | |
[ref]
The audit system writes data to | |
| Group Configure auditd Rules for Comprehensive Auditing | |
[ref]
The
Auditing rules at startup are controlled by the file /etc/audit/audit.rules.
Add rules to it to meet the auditing requirements for your organization.
Each line in /etc/audit/audit.rules represents a series of arguments
that can be passed to auditctl and can be individually tested
during runtime. See documentation in /usr/share/doc/audit-VERSION and
in the related man pages for more details.
If copying any example audit rulesets from /usr/share/doc/audit-VERSION,
be sure to comment out the
lines containing arch= which are not appropriate for your system's
architecture. Then review and understand the following rules,
ensuring rules are activated as needed for the appropriate
architecture.
After reviewing all the rules, reading the following sections, and editing as needed, the new rules can be activated as follows: $ sudo service auditd restart | |
| Group Record Attempts to Alter Logon and Logout Events | |
[ref]
The audit system already collects login information for all users
and root. If the -w /var/log/tallylog -p wa -k logins -w /var/run/faillock/ -p wa -k logins -w /var/log/lastlog -p wa -k loginsIf the auditd daemon is configured to use the auditctl
utility to read audit rules during daemon startup, add the following lines to
/etc/audit/audit.rules file in order to watch for unattempted manual
edits of files involved in storing logon events:
-w /var/log/tallylog -p wa -k logins -w /var/run/faillock/ -p wa -k logins -w /var/log/lastlog -p wa -k logins | |
| Group Records Events that Modify Date and Time Information | |
[ref] Arbitrary changes to the system time can be used to obfuscate nefarious activities in log files, as well as to confuse network services that are highly dependent upon an accurate system time. All changes to the system time should be audited. | |
| Group Record Unauthorized Access Attempts Events to Files (unsuccessful) | |
[ref]
At a minimum, the audit system should collect unauthorized file
accesses for all users and root. Note that the "-F arch=b32" lines should be
present even on a 64 bit system. These commands identify system calls for
auditing. Even if the system is 64 bit it can still execute 32 bit system
calls. Additionally, these rules can be configured in a number of ways while
still achieving the desired effect. An example of this is that the "-S" calls
could be split up and placed on separate lines, however, this is less efficient.
Add the following to -a always,exit -F arch=b32 -S creat,open,openat,open_by_handle_at,truncate,ftruncate -F exit=-EACCES -F auid>=500 -F auid!=unset -F key=access
-a always,exit -F arch=b32 -S creat,open,openat,open_by_handle_at,truncate,ftruncate -F exit=-EPERM -F auid>=500 -F auid!=unset -F key=access
If your system is 64 bit then these lines should be duplicated and the
arch=b32 replaced with arch=b64 as follows:
-a always,exit -F arch=b64 -S creat,open,openat,open_by_handle_at,truncate,ftruncate -F exit=-EACCES -F auid>=500 -F auid!=unset -F key=access
-a always,exit -F arch=b64 -S creat,open,openat,open_by_handle_at,truncate,ftruncate -F exit=-EPERM -F auid>=500 -F auid!=unset -F key=access | |
| Group Record Information on the Use of Privileged Commands | |
[ref] At a minimum, the audit system should collect the execution of privileged commands for all users and root. | |
| Group Record Information on Kernel Modules Loading and Unloading | |
[ref] To capture kernel module loading and unloading events, use following lines, setting ARCH to either b32 for 32-bit system, or having two lines for both b32 and b64 in case your system is 64-bit: -w /usr/sbin/insmod -p x -k modules -w /usr/sbin/rmmod -p x -k modules -w /usr/sbin/modprobe -p x -k modules -a always,exit -F arch=ARCH -S init_module,delete_module -F key=modulesPlace to add the lines depends on a way auditd daemon is configured. If it is configured
to use the augenrules program (the default), add the lines to a file with suffix
.rules in the directory /etc/audit/rules.d.
If the auditd daemon is configured to use the auditctl utility,
add the lines to file /etc/audit/audit.rules. | |
| Group Record File Deletion Events by User | |
[ref]
At a minimum, the audit system should collect file deletion events
for all users and root. If the -a always,exit -F arch=ARCH -S rmdir,unlink,unlinkat,rename,renameat -F auid>=500 -F auid!=unset -F key=deleteIf the auditd daemon is configured to use the auditctl
utility to read audit rules during daemon startup, add the following line to
/etc/audit/audit.rules file, setting ARCH to either b32 or b64 as
appropriate for your system:
-a always,exit -F arch=ARCH -S rmdir,unlink,unlinkat,rename,renameat -F auid>=500 -F auid!=unset -F key=delete | |
| Group Record Events that Modify the System's Discretionary Access Controls | |
[ref]
At a minimum, the audit system should collect file permission
changes for all users and root. Note that the "-F arch=b32" lines should be
present even on a 64 bit system. These commands identify system calls for
auditing. Even if the system is 64 bit it can still execute 32 bit system
calls. Additionally, these rules can be configured in a number of ways while
still achieving the desired effect. An example of this is that the "-S" calls
could be split up and placed on separate lines, however, this is less efficient.
Add the following to -a always,exit -F arch=b32 -S chmod,fchmod,fchmodat -F auid>=500 -F auid!=unset -F key=perm_mod
-a always,exit -F arch=b32 -S chown,fchown,fchownat,lchown -F auid>=500 -F auid!=unset -F key=perm_mod
-a always,exit -F arch=b32 -S setxattr,lsetxattr,fsetxattr,removexattr,lremovexattr,fremovexattr -F auid>=500 -F auid!=unset -F key=perm_mod
If your system is 64 bit then these lines should be duplicated and the
arch=b32 replaced with arch=b64 as follows:
-a always,exit -F arch=b64 -S chmod,fchmod,fchmodat -F auid>=500 -F auid!=unset -F key=perm_mod
-a always,exit -F arch=b64 -S chown,fchown,fchownat,lchown -F auid>=500 -F auid!=unset -F key=perm_mod
-a always,exit -F arch=b64 -S setxattr,lsetxattr,fsetxattr,removexattr,lremovexattr,fremovexattr -F auid>=500 -F auid!=unset -F key=perm_mod | |
| Group Record Execution Attempts to Run SELinux Privileged Commands | |
[ref] At a minimum, the audit system should collect the execution of SELinux privileged commands for all users and root. | |
| Group Set Boot Loader Password | |
[ref] During the boot process, the boot loader is responsible for starting the execution of the kernel and passing options to it. The boot loader allows for the selection of different kernels - possibly on different partitions or media. The default Red Hat Enterprise Linux 6 boot loader for x86 systems is called GRUB2. Options it can pass to the kernel include single-user mode, which provides root access without any authentication, and the ability to disable SELinux. To prevent local users from modifying the boot parameters and endangering security, protect the boot loader configuration with a password and ensure its configuration file's permissions are set properly. | |
| Group SELinux | |
[ref]
SELinux is a feature of the Linux kernel which can be
used to guard against misconfigured or compromised programs.
SELinux enforces the idea that programs should be limited in what
files they can access and what actions they can take.
| |
| Group SELinux - Booleans | |
[ref] Enable or Disable runtime customization of SELinux system policies without having to reload or recompile the SELinux policy. | |
| Group Installing and Maintaining Software | |
[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 | |
[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 | |
[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.
| |
| Group Verify Integrity with RPM | |
[ref] The RPM package management system includes the ability to verify the integrity of installed packages by comparing the installed files with information about the files taken from the package metadata stored in the RPM database. Although an attacker could corrupt the RPM database (analogous to attacking the AIDE database as described above), this check can still reveal modification of important files. To list which files on the system differ from what is expected by the RPM database: $ rpm -qVaSee the man page for rpm to see a complete explanation of each column. | |
| Group Verify Integrity with AIDE | |
[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 | |
| Group Federal Information Processing Standard (FIPS) | |
[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.
| |
| Group Operating System Vendor Support and Certification | |
[ref] The assurance of a vendor to provide operating system support and maintenance for their product is an important criterion to ensure product stability and security over the life of the product. A certified product that follows the necessary standards and government certification requirements guarantees that known software vulnerabilities will be remediated, and proper guidance for protecting and securing the operating system will be given. | |
| Group System Cryptographic Policies | |
[ref]
Linux has the capability to centrally configure cryptographic polices. The command
| |
| Group Endpoint Protection Software | |
[ref] Endpoint protection security software that is not provided or supported by Red Hat can be installed to provide complementary or duplicative security capabilities to those provided by the base platform. Add-on software may not be appropriate for some specialized systems. | |
| Group McAfee Endpoint Security Software | |
[ref] In DoD environments, McAfee Host-based Security System (HBSS) and VirusScan Enterprise for Linux (VSEL) is required to be installed on all systems. | |
| Group McAfee Host-Based Intrusion Detection Software (HBSS) | |
[ref] McAfee Host-based Security System (HBSS) is a suite of software applications used to monitor, detect, and defend computer networks and systems. | |
| Group Disk Partitioning | |
[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
| |
| Group SAP Specific Requirement | |
[ref] SAP (Systems, Applications and Products in Data Processing) is enterprise software to manage business operations and customer relations. The following section contains SAP specific requirement that is not part of standard or common OS setting. | |
| Group Updating Software | |
[ref]
The | |
| Group GNOME Desktop Environment | |
[ref]
GNOME is a graphical desktop environment bundled with many Linux distributions that
allow users to easily interact with the operating system graphically rather than
textually. The GNOME Graphical Display Manager (GDM) provides login, logout, and user
switching contexts as well as display server management.
| |
| Group GNOME System Settings | |
[ref] GNOME provides configuration and functionality to a graphical desktop environment that changes grahical configurations or allow a user to perform actions that users normally would not be able to do in non-graphical mode such as remote access configuration, power policies, Geo-location, etc. Configuring such settings in GNOME will prevent accidential graphical configuration changes by users from taking place. | |
| Group GNOME Media Settings | |
[ref] GNOME media settings that apply to the graphical interface. | |
| Group GNOME Remote Access Settings | |
[ref] GNOME remote access settings that apply to the graphical interface. | |
| Group Configure GNOME Screen Locking | |
[ref]
In the default GNOME desktop, the screen can be locked
by choosing Lock Screen from the System menu.
| |
| Group GNOME Network Settings | |
[ref] GNOME network settings that apply to the graphical interface. | |
| Group Configure GNOME Login Screen | |
[ref]
In the default GNOME desktop, the login is displayed after system boot
and can display user accounts, allow users to reboot the system, and allow users to
login automatically and/or with a guest account. The login screen should be configured
to prevent such behavior.
| |
| Group Sudo | |
[ref]
| |
| Group Set Boot Loader Password | |
[ref] During the boot process, the boot loader is responsible for starting the execution of the kernel and passing options to it. The boot loader allows for the selection of different kernels - possibly on different partitions or media. The default Red Hat Enterprise Linux boot loader for x86 systems is called GRUB. Options it can pass to the kernel include single-user mode, which provides root access without any authentication, and the ability to disable SELinux. To prevent local users from modifying the boot parameters and endangering security, protect the boot loader configuration with a password and ensure its configuration file's permissions are set properly. | |
| Group Account and Access Control | |
[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 Red Hat Enterprise Linux 6. | |
| Group Warning Banners for System Accesses | |
[ref]
Each system should expose as little information about
itself as possible.
| |
| Group Implement a GUI Warning Banner | |
[ref] In the default graphical environment, users logging directly into the system are greeted with a login screen provided by the GNOME Display Manager (GDM). The warning banner should be displayed in this graphical environment for these users. The following sections describe how to configure the GDM login banner. | |
| Group Protect Physical Console Access | |
[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 | |
[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.
| |
| Group Configure Console Screen Locking | |
[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. | |
| Group Hardware Tokens for Authentication | |
[ref] The use of hardware tokens such as smart cards for system login provides stronger, two-factor authentication than using a username and password. In Red Hat Enterprise Linux servers and workstations, hardware token login is not enabled by default and must be enabled in the system settings. | |
| Group Protect Accounts by Restricting Password-Based Login | |
[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 | |
| Group Verify Proper Storage and Existence of Password Hashes | |
[ref]
By default, password hashes for local accounts are stored
in the second field (colon-separated) in
| |
| Group Set Account Expiration Parameters | |
[ref]
Accounts can be configured to be automatically disabled
after a certain time period,
meaning that they will require administrator interaction to become usable again.
Expiration of accounts after inactivity can be set for all accounts by default
and also on a per-account basis, such as for accounts that are known to be temporary.
To configure automatic expiration of an account following
the expiration of its password (that is, after the password has expired and not been changed),
run the following command, substituting $ sudo chage -I NUM_DAYS USERAccounts, such as temporary accounts, can also be configured to expire on an explicitly-set date with the -E option.
The file /etc/default/useradd controls
default settings for all newly-created accounts created with the system's
normal command line utilities.Warning:
This will only apply to newly created accounts | |
| Group Restrict Root Logins | |
[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 | |
| Group Set Password Expiration Parameters | |
[ref]
The file $ sudo chage -M 180 -m 7 -W 7 USER | |
| Group Protect Accounts by Configuring PAM | |
[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.
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. Warning:
Running authconfig or system-config-authentication
will re-write the PAM configuration files, destroying any manually
made changes and replacing them with a series of system defaults.
One reference to the configuration file syntax can be found at
http://www.linux-pam.org/Linux-PAM-html/sag-configuration-file.html. | |
| Group Set Password Hashing Algorithm | |
[ref]
The system's default algorithm for storing password hashes in
| |
| Group Set Lockouts for Failed Password Attempts | |
[ref]
The 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. | |
| Group Set Password Quality Requirements | |
[ref]
The default | |
| Group Set Password Quality Requirements with pam_pwquality | |
[ref]
The 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 = 3The arguments can be modified to ensure compliance with your organization's security policy. Discussion of each parameter follows. | |
| Group Set Password Quality Requirements, if using pam_cracklib | |
[ref]
The password requisite pam_cracklib.so try_first_pass retry=3and then alter it to read: password required pam_cracklib.so try_first_pass retry=3 maxrepeat=3 minlen=14 dcredit=-1 ucredit=-1 ocredit=-1 lcredit=-1 difok=4If no such line exists, add one as the first line of the password section in /etc/pam.d/system-auth.
The arguments can be modified to ensure compliance with
your organization's security policy. Discussion of each parameter follows.Warning:
Note that the password quality requirements are not enforced for the
root account for some reason. | |
| Group Secure Session Configuration Files for Login Accounts | |
[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 No Dangerous Directories Exist in Root's Path | |
[ref] The active path of the root account can be obtained by starting a new root shell and running: # echo $PATHThis will produce a colon-separated list of directories in the path. Certain path elements could be considered dangerous, as they could lead to root executing unknown or untrusted programs, which could contain malicious code. Since root may sometimes work inside untrusted directories, the . character, which represents the
current directory, should never be in the root path, nor should any
directory which can be written to by an unprivileged or
semi-privileged (system) user.
It is a good practice for administrators to always execute privileged commands by typing the full path to the command. | |
| Group Ensure that Users Have Sensible Umask Values | |
[ref]
The umask setting controls the default permissions
for the creation of new files.
With a default | |
| Group Introduction | |
[ref] The purpose of this guidance is to provide security configuration recommendations and baselines for the Red Hat Enterprise Linux 6 operating system. Recommended settings for the basic operating system are provided, as well as for many network services that the system can provide to other systems. The guide is intended for system administrators. Readers are assumed to possess basic system administration skills for Unix-like systems, as well as some familiarity with the product's documentation and administration conventions. Some instructions within this guide are complex. All directions should be followed completely and with understanding of their effects in order to avoid serious adverse effects on the system and its security. | |
| Group How to Use This Guide | |
[ref] Readers should heed the following points when using the guide. | |
| Group Read Sections Completely and in Order | |
[ref] Each section may build on information and recommendations discussed in prior sections. Each section should be read and understood completely; instructions should never be blindly applied. Relevant discussion may occur after instructions for an action. | |
| Group Formatting Conventions | |
[ref]
Commands intended for shell execution, as well as configuration file text,
are featured in a | |
| Group Root Shell Environment Assumed | |
[ref]
Most of the actions listed in this document are written with the
assumption that they will be executed by the root user running the
| |
| Group Reboot Required | |
[ref] A system reboot is implicitly required after some actions in order to complete the reconfiguration of the system. In many cases, the changes will not take effect until a reboot is performed. In order to ensure that changes are applied properly and to test functionality, always reboot the system after applying a set of recommendations from this guide. | |
| Group Test in Non-Production Environment | |
[ref] This guidance should always be tested in a non-production environment before deployment. This test environment should simulate the setup in which the system will be deployed as closely as possible. | |
| Group General Principles | |
[ref] The following general principles motivate much of the advice in this guide and should also influence any configuration decisions that are not explicitly covered. | |
| Group Run Different Network Services on Separate Systems | |
[ref] Whenever possible, a server should be dedicated to serving exactly one network service. This limits the number of other services that can be compromised in the event that an attacker is able to successfully exploit a software flaw in one network service. | |
| Group Encrypt Transmitted Data Whenever Possible | |
[ref] Data transmitted over a network, whether wired or wireless, is susceptible to passive monitoring. Whenever practical solutions for encrypting such data exist, they should be applied. Even if data is expected to be transmitted only over a local network, it should still be encrypted. Encrypting authentication data, such as passwords, is particularly important. Networks of Red Hat Enterprise Linux 6 machines can and should be configured so that no unencrypted authentication data is ever transmitted between machines. | |
| Group Configure Security Tools to Improve System Robustness | |
[ref] Several tools exist which can be effectively used to improve a system's resistance to and detection of unknown attacks. These tools can improve robustness against attack at the cost of relatively little configuration effort. In particular, this guide recommends and discusses the use of host-based firewalling, SELinux for protection against vulnerable services, and a logging and auditing infrastructure for detection of problems. | |
| Group Least Privilege | |
[ref]
Grant the least privilege necessary for user accounts and software to perform tasks.
For example, | |
| Group Minimize Software to Minimize Vulnerability | |
[ref] The simplest way to avoid vulnerabilities in software is to avoid installing that software. On Red Hat Enterprise Linux 6,the RPM Package Manager (originally Red Hat Package Manager, abbreviated RPM) allows for careful management of the set of software packages installed on a system. Installed software contributes to system vulnerability in several ways. Packages that include setuid programs may provide local attackers a potential path to privilege escalation. Packages that include network services may give this opportunity to network-based attackers. Packages that include programs which are predictably executed by local users (e.g. after graphical login) may provide opportunities for trojan horses or other attack code to be run undetected. The number of software packages installed on a system can almost always be significantly pruned to include only the software for which there is an environmental or operational need. |