Security-Enhanced Linux

Security-Enhanced Linux (SELinux) is a Linux kernel security module that provides the mechanism for supporting access control security policies, including United States Department of Defense-style mandatory access controls (MAC). It is a set of kernel modifications and user-space tools that can be added to various Linux distributions. Its architecture strives to separate enforcement of security decisions from the security policy itself and streamlines the volume of software charged with security policy enforcement. The key concepts underlying SELinux can be traced to several earlier projects by the United States National Security Agency.

It has been integrated into the mainline Linux kernel since version 2.6, on 8 August 2003.

Overview
The United States National Security Agency (NSA), the original primary developer of SELinux, released the first version to the open source development community under the GNU GPL on December 22, 2000. The software merged into the mainline Linux kernel 2.6.0-test3, released on 8 August 2003. Other significant contributors include Network Associates, Red Hat, Secure Computing Corporation, Tresys Technology, and Trusted Computer Solutions. Experimental ports of the FLASK/TE implementation have been made available via the TrustedBSD Project for the FreeBSD and Darwin operating systems.

From NSA Security-enhanced Linux Team:


 * "NSA Security-enhanced Linux is a set of patches to the Linux kernel and some utilities to incorporate a strong, flexible mandatory access control (MAC) architecture into the major subsystems of the kernel. It provides an enhanced mechanism to enforce the separation of information based on confidentiality and integrity requirements, which allows threats of tampering and bypassing of application security mechanisms to be addressed and enables the confinement of damage that can be caused by malicious or flawed applications. It includes a set of sample security policy configuration files designed to meet common, general-purpose security goals."

(SELinux has been integrated into version 2.6 series of the Linux kernel, and separate patches are now unnecessary; the above is a historical quotation.)

Security-Enhanced Linux implements the Flux Advanced Security Kernel (FLASK) integrated in some versions of the Linux kernel with a number of utilities designed to demonstrate the value of mandatory access controls to the Linux community and how such controls could be added to Linux. Such a kernel contains architectural components prototyped in the Fluke operating system. These provide general support for enforcing many kinds of mandatory access control policies, including those based on the concepts of type enforcement, role-based access control, and multilevel security. FLASK, in turn, was based on DTOS, a Mach-derived Distributed Trusted Operating System, as well as Trusted Mach, a research project from Trusted Information Systems that had an influence on the design and implementation of DTOS.

A Linux kernel integrating SELinux enforces mandatory access-control policies that confine user programs and system servers to the minimum amount of privilege they require to do their jobs. This reduces or eliminates the ability of these programs and daemons to cause harm when compromised (via buffer overflows or misconfigurations, for example). This confinement mechanism operates independently of the traditional Linux (discretionary) access control mechanisms. It has no concept of a "root" super-user, and does not share the well-known shortcomings of the traditional Linux security mechanisms (such as a dependence on setuid/setgid binaries).

The security of an "unmodified" Linux system (a system without SELinux) depends on the correctness of the kernel, of all the privileged applications, and of each of their configurations. A problem in any one of these areas may allow the compromise of the entire system. In contrast, the security of a "modified" system (based on an SELinux kernel) depends primarily on the correctness of the kernel and its security-policy configuration. While problems with the correctness or configuration of applications may allow the limited compromise of individual user programs and system daemons, they do not pose a threat to the security of other user programs and system daemons or to the security of the system as a whole.

From a purist perspective, SELinux provides a hybrid of concepts and capabilities drawn from mandatory access controls, mandatory integrity controls, role-based access control (RBAC), and type enforcement architecture. Third-party tools enable one to build a variety of security policies.

Users, policies and security contexts
SELinux users and roles are not related to the actual system users and roles. For every current user or process, SELinux assigns a three string context consisting of a role, user name, and domain (or type). This system is more flexible than normally required: as a rule, most of the real users share the same SELinux username, and all access control is managed through the third tag, the domain. Circumstance for when the user is allowed to get into a certain domain must be configured in the policies. The command runcon allows for the launching of a process into an explicitly specified context (user, role and domain), but SELinux may deny the transition if it is not approved by the policy configuration.

Files, network ports, and other hardware also have an SELinux context, consisting of a name, role (seldom used), and type. In case of the file systems, mapping between files and the security contexts is called labeling. The labeling is defined in policy files but can also be manually adjusted without changing the policies. Hardware types are quite detailed, for instance, bin_t (all files in the folder /bin) or postgresql_port_t (PostgreSQL port, 5432). The SELinux context for a remote file system can be specified explicitly at mount time. SELinux adds the -Z switch to the shell commands ls, ps, and some others, allowing the security context of the files or process to be seen.

Typical policy rules often consist of explicit permissions; which domains the user must possess to perform certain actions with the given target (read, execute, or, in case of network port, bind or connect), and so on. More complex mappings are also possible, involving roles and security levels. A typical policy consists of a mapping (labeling) file, a rule file, and an interface file, that define the domain transition. These three files must be compiled together with the SELinux tools to produce a single policy file. The resulting policy file can be loaded into the kernel, making it active. Loading and unloading policies does not require a reboot. The policy files are either hand written or can be generated from the more user friendly SELinux management tool. They are normally tested in permissive mode first, where violations are logged but allowed. The audit2allow tool can be used later to produce additional rules that extend the policy to allow all legitimate activities of the application being confined.

Features

 * Clean separation of policy from enforcement
 * Well-defined policy interfaces
 * Support for applications querying the policy and enforcing access control (for example, crond running jobs in the correct context)
 * Independent of specific policies and policy languages
 * Independent of specific security label formats and contents
 * Individual labels and controls for kernel objects and services
 * Support for policy changes
 * Separate measures for protecting system integrity (domain-type) and data confidentiality (multilevel security)
 * Flexible policy
 * Controls over process initialization and inheritance and program execution
 * Controls over file systems, directories, files, and open file descriptors
 * Controls over sockets, messages, and network interfaces
 * Controls over use of "capabilities"
 * Cached information on access-decisions via the AVC (Access Vector Cache)

Usage
SELinux can potentially control which activities a system allows each user, process and daemon, with very precise specifications. However, it is mostly used to confine daemons like database engines or web servers that have more clearly-defined data access and activity rights. This limits potential harm from a confined daemon that becomes compromised. Ordinary user-processes often run in the unconfined domain, not restricted by SELinux but still restricted by the classic Linux access rights.

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Usage examples
To put SELinux into enforcing mode: $ sudo setenforce 1 To query the SELinux status: $ getenforce

Implementations
SELinux is available with commercial support as part of Red Hat Enterprise Linux (RHEL) version 4 and all future releases. This presence is also reflected in corresponding versions of CentOS and Scientific Linux. The supported policy in RHEL4 is the targeted policy which aims for maximum ease of use and thus is not as restrictive as it might be. Future versions of RHEL are planned to have more targets in the targeted policy which will mean more restrictive policies.

In free community supported GNU/Linux distributions, Fedora was one of the earliest adopters, including support for it by default since Fedora Core 2. Other distributions include support for it such as Debian as of the etch release and Ubuntu as of 8.04 Hardy Heron. As of version 11.1, openSUSE contains SELinux “basic enablement”. SUSE Linux Enterprise 11 features SELinux as a “technology preview”.

The earliest work directed toward standardizing an approach toward provision of mandatory and discretionary access controls (MAC and DAC) within a UNIX (more precisely, POSIX) computing environment can be attributed to the National Security Agency's Trusted UNIX (TRUSIX) Working Group, which met from 1987 to 1991 and published one Rainbow Book (#020A) and produced a formal model and associated evaluation evidence prototype (#020B) that was ultimately unpublished. It was sponsored by Chet Coates and Mario Tinto of the NSA's National Computer Security Center, and managed by Dr. Charles Testa and Bruce Wilner of Infosystems Technology (Greenbelt, Maryland; later, Falls Church, Virginia), the crucial architects of the TRUSIX project, and members of its Modeling Subcommittee – Steve Bunch, Dr. Frank Knowles, Dr. J. Eric Roskos, Larry Wehr, and Bruce Wilner. Their efforts, particularly as critics of the less technically profound work of the TRUSIX Access Control List (ACL) Subcommittee, survive in the IEEE POSIX 1003.6 "security extensions for portable operating systems environments" specification.

Comparison with AppArmor
SELinux represents one of several possible approaches to the problem of restricting the actions that installed software can take. Another popular alternative, available on Novell's SuSE Linux and Canonical's Ubuntu platform, is called AppArmor. AppArmor was developed as a component to the now-defunct Immunix Linux platform. Because AppArmor and SELinux differ radically from one another, they form distinct alternatives for software control. Whereas SELinux re-invents certain concepts in order to provide access to a more expressive set of policy choices, AppArmor was designed to be simple by extending the same administrative semantics used for DAC up to the mandatory access control level.

There are several key differences:
 * One important difference is that AppArmor identifies file system objects by path name instead of inode. This means that, for example, a file that is inaccessible may become accessible under AppArmor when a hard link is created to it, while SELinux would deny access through the newly created hard link.
 * As a result, AppArmor can be said to not be a Type Enforcement system, as files are not assigned a type, they are merely referenced in a configuration file.
 * SELinux and AppArmor also differ significantly in how they are administered and how they integrate into the system.
 * Since it endeavors to recreate traditional DAC controls with MAC-level enforcement, AppArmor's set of operations is also considerably lower than those available under most SELinux implementations. For example, AppArmor's set of operations consist of: read, write, append, execute, lock, and link. Most SELinux implentations will support numbers of operations orders of magnitude more than that. For example, SELinux will usually support those same permissions, but also includes controls for mknod, binding to network sockets, implicit use of POSIX capabilities, loading and unloading kernel modules, various means of accessing shared memory, etc.
 * There are no controls in AppArmor for categorically bounding POSIX capabilities. Since the current implementation of capabilities contains no notion of a subject for the operation (only the actor and the operation itself) it is usually the job of the MAC layer to prevent privileged operations on files outside the actor's enforced realm of control (i.e. "Sandbox"). AppArmor can prevent its own policy from being altered, and prevent filesystems from being mounted/unmounted, but does nothing to prevent users from stepping outside their approved realms of control.
 * For example, it may be deemed beneficial for help desk employees to change ownership or permissions on certain files even if they don't own them (for example, on a departmental file share). You obviously don't want to give the user(s) root on the box so you give them CAP_FOWNER or CAP_DAC_OVERRIDE. Under SELinux you (or your platform vendor) can configure SELinux to deny all capabilities to otherwise unconfined users, then create confined domains for the employee to be able to transition into after logging in, one that can exercise those capabilities, but only upon files of the appropriate type.
 * There is no notion of multi-level security with AppArmor, thus there is no hard BLP or Biba enforcement available.
 * AppArmor configuration is done using solely regular flat files. SELinux (by default in most implementations) uses a combination of flat files (used by administrators and developers to write human readable policy before it's compiled) and extended attributes.
 * SELinux supports the concept of a "remote policy server" (configurable via /etc/selinux/semanage.conf) as an alternative source for policy configuration. Central management of AppArmor is usually complicated considerably since administrators must decide between configuration deployment tools being ran as root (to allow policy updates) or configured manually on each server.

Other systems
Isolation of processes can also be accomplished by mechanisms like virtualization; the OLPC project, for example, in its first implementation sandboxed individual applications in lightweight Vservers.

Security-Enhanced Android
The NSA have adopted some of the SE Linux concepts in Security-Enhanced Android.