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In computing, privilege is defined as the delegation of authority over a computer system. A privilege allows a user to perform an action. Examples of various privileges include the ability to create a file in a directory, or to read or delete a file, access a device, or have read or write permission to a socket for communicating over the Internet.
Users who have been delegated extra levels of control are called privileged. Users who lack most privileges are defined as unprivileged, regular, or normal users.
Privileges can either be automatic, granted, or applied for.
An automatic privilege exists when there is no requirement to have permission to perform an action. For example, on systems where people are required to log into a system to use it, logging out will not require a privilege. Systems that do not implement file protection - such as MS-DOS - essentially give unlimited privilege to perform any action on a file.
A granted privilege exists as a result of presenting some credential to the privilege granting authority. This is usually accomplished by logging on to a system with a username and password, and if the username and password supplied are correct, the user is granted additional privileges.
A privilege is applied for by either an executed program issuing a request for advanced privileges, or by running some program to apply for the additional privileges. An example of a user applying for additional privileges is provided by the sudo command to run a command as the root user, or by the Kerberos authentication system.
Modern processor architectures have multiple CPU modes that allows the OS to run at different privilege levels. Some processors have two levels (such as user and supervisor); i386+ processors have four levels (#0 with the most, #3 with the least privileges). Tasks are tagged with a privilege level. Resources (segments, pages, ports, etc.) and the privileged instructions are tagged with a demanded privilege level. When a task tries to use a resource, or execute a privileged instruction, the processor determines whether it has the permission (if not, a "protection fault" interrupt is generated). This prevents user tasks from damaging the OS or each other.
In computer programming, exceptions related to privileged instruction violations may be caused when an array has been accessed out of bounds or an invalid pointer has been dereferenced when the invalid memory location referenced is a privileged location, such as one controlling device input/output. This is particularly more likely to occur in programming languages such as C, which use pointer arithmetic or do not check array bounds automatically.
On Unix-like systems, the superuser (commonly known as 'root') owns all the privileges. Ordinary users are granted only enough permissions to accomplish their most common tasks. UNIX systems have built-in security features. Most users cannot set up a new user account nor do other administrative procedures. The user “root” is a special user, something called super-user, which can do anything at all on the system. This high degree power is necessary to fully administer a UNIX system, but it also allows its user to make a mistake and cause system problems.
Unprivileged users usually cannot:
On Windows NT-based systems, privileges are delegated in varying degrees. These delegations can be defined using the Local Security Policy Manager (SECPOL.MSC). The following is an abbreviated list of the default assignments:
Windows defines a number of administrative privileges that can be assigned individually to users and/or groups. An account (user) holds only the privileges granted to it, either directly or indirectly through group memberships. Upon installation a number of groups and accounts are created and privileges are granted to them. However, these grants can be changed at a later time or though a group policy. Unlike Linux, no privileges are implicitly or permanently granted to a specific account.
Some administrative privileges (e.g. taking ownership of or restoring arbitrary files) are so powerful that if used with malicious intent they could allow the entire system to be compromised. With user account control (on by default since Windows Vista) Windows will strip the user token of these privileges at login. Thus, if a user logs in with an account with broad system privileges, he/she will still not be running with these system privileges. Whenever the user wants to perform administrative actions requiring any of the system privileges he/she will have to do this from an elevated process. When launching an elevated process, the user is made aware that his/her administrative privileges are being asserted through a prompt requiring his/her consent. Not holding privileges until actually required is in keeping with the Principle of least privilege.
Elevated processes will run with the full privileges of the user, not the full privileges of the system. Even so, the privileges of the user may still be more than what is required for that particular process, thus not completely least privilege.
The DOS-based Windows ME, Windows 98, Windows 95, and previous versions of non-NT Windows only operated on the FAT filesystem and did not support filesystem permissions., and therefore privileges are effectively defeated on Windows NT-based systems that do not use the NTFS file system.
The names used in the Windows source code end in either "Privilege" or "LogonRight". This has led to some confusion about what the full set of all these "Rights" and "Privileges" should be called.
You can set permissions at the file level only if the files are stored on an NTFS volume.
User rights include logon rights and privileges.
The following is a list of logon user rights [...] SeInteractiveLogonRight [...] SeDebugPrivilege
NTRights.Exe [...] Grants/Revokes NT-Rights [...] valid NTRights are: SeCreateTokenPrivilege