Docs/Drafts/SELinux User Guide/SELinux Content Specification/SELinux Content Specification Preface

SELinux Introduction
On Linux operating systems, everything is represented as a file. For example, a hard disk can be represented as the  file, and processes, such as Mozilla Firefox, are represented as files in the proc file system. These files are called objects. Linux operating systems use a Discretionary Access Control (DAC) system, that defines access to these objects. Users have access to change permissions for files and directories that they own. They could, for example, make their home directory world-readable, potentially allowing access to privileged information from other users, or giving processes, such as a Web server, access to serve these files.

Security-Enhanced Linux (SELinux) provides a Mandatory Access Control (MAC) system -- that is built into the Linux kernel -- for Linux operating systems. MAC restricts the control users have over the files and directories that they create. SELinux allows files, and therefore everything on a Linux system, to be labeled. MAC rules allow all available information to be used to make access decisions, instead of only a user and a group. MAC rules are checked after DAC rules.

SELinux Terminology
The order of the items in this section was taken from .

The following terms are used throughout this guide:


 * Object:


 * Subject:


 * Label or security context:


 * SELinux user identity:


 * Role:


 * Type:


 * Domain:


 * Access Vector Cache (AVC):


 * Targeted Policy

What SELinux Can Do
With SELinux, processes (subjects), such as the Apache HTTP server, run in a restricted domain. Files (objects) are labeled with a type. This type is used by Type Enforcement, which is used by MAC. SELinux policy defines the interaction subjects have with objects. This means that if the Apache HTTP server is compromised, the attacker only has access to files labeled with the correct type. Each file is labeled with an SELinux user identify, a role, and a type:.

SELinux offers:


 * Type Enforcement (TE): fine-grained access control. MAC allow/disallow actions are checked after DAC permissions. All Files are labeled with a type. Access is only granted if it is specifically defined - the default action is to deny access. This prevents subjects (processes), such as Samba and FTP, from accessing files they should not have access to, for example, files in user home directories.


 * Fine-grained access control: Type Enforcement allows for fine-grained access control. For example, the Apache HTTP server can only access files that are labeled with the  type, and not files that are labeled with the   type, which is the type used for files in user home directories.


 * Preventation against privilege escalation: subjects run in restricted domains. For a process, the type attribute defines which domain the process runs in. By default, a subject running in one domain can not access another domain. If a Web server is running in a protected domain, and that Web server is compromised, an attacker can only access files that the Web server has access to. SELinux also provides confined user types. Depending on the type selected, this can prevent: the use of X windows, executing files in home directories, network access, executing binaries that have the set user ID bit set, and so on.


 * Role Based Access Control (RBAC): every object (files, sockets, and so on) and subject (processes) is labeled with an SELinux user identity, a role, and a type. For a subject, the type defines the restricted domain the process runs in. The role attribute defines which SELinux user identities can access which domains.


 * Logging:

Policy Overview

 * Brief overview of SELinux Policy: 
 * Hook in the kernel, SELinux enforces the policy.

Examples
Processes being compromised, but not allowing an attacker to take over the whole system

Performance
Part of the SELinux LSM module is the security server. The security server contains policy rules, which define what access is allowed. Hooks in the Linux kernel communicate with the security server for access decisions, such as allowing or disallowing a process access to a file. An Access Vector Cache (AVC) caches decisions made by this server. This decreases how often rules in the security server need to be checked for, which increases performance.

When running SELinux in permissive mode, access rules are still checked; however, when a denial occurs, the denial is logged, and access is allowed. There is no performance decrease when SELinux is disabled, as the SELinux module is not registered with the kernel.