mirror of https://gitee.com/openkylin/linux.git
583 lines
20 KiB
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583 lines
20 KiB
Plaintext
====================
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CREDENTIALS IN LINUX
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====================
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By: David Howells <dhowells@redhat.com>
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Contents:
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(*) Overview.
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(*) Types of credentials.
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(*) File markings.
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(*) Task credentials.
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- Immutable credentials.
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- Accessing task credentials.
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- Accessing another task's credentials.
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- Altering credentials.
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- Managing credentials.
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(*) Open file credentials.
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(*) Overriding the VFS's use of credentials.
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========
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OVERVIEW
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========
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There are several parts to the security check performed by Linux when one
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object acts upon another:
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(1) Objects.
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Objects are things in the system that may be acted upon directly by
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userspace programs. Linux has a variety of actionable objects, including:
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- Tasks
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- Files/inodes
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- Sockets
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- Message queues
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- Shared memory segments
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- Semaphores
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- Keys
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As a part of the description of all these objects there is a set of
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credentials. What's in the set depends on the type of object.
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(2) Object ownership.
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Amongst the credentials of most objects, there will be a subset that
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indicates the ownership of that object. This is used for resource
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accounting and limitation (disk quotas and task rlimits for example).
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In a standard UNIX filesystem, for instance, this will be defined by the
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UID marked on the inode.
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(3) The objective context.
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Also amongst the credentials of those objects, there will be a subset that
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indicates the 'objective context' of that object. This may or may not be
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the same set as in (2) - in standard UNIX files, for instance, this is the
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defined by the UID and the GID marked on the inode.
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The objective context is used as part of the security calculation that is
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carried out when an object is acted upon.
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(4) Subjects.
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A subject is an object that is acting upon another object.
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Most of the objects in the system are inactive: they don't act on other
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objects within the system. Processes/tasks are the obvious exception:
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they do stuff; they access and manipulate things.
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Objects other than tasks may under some circumstances also be subjects.
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For instance an open file may send SIGIO to a task using the UID and EUID
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given to it by a task that called fcntl(F_SETOWN) upon it. In this case,
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the file struct will have a subjective context too.
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(5) The subjective context.
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A subject has an additional interpretation of its credentials. A subset
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of its credentials forms the 'subjective context'. The subjective context
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is used as part of the security calculation that is carried out when a
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subject acts.
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A Linux task, for example, has the FSUID, FSGID and the supplementary
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group list for when it is acting upon a file - which are quite separate
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from the real UID and GID that normally form the objective context of the
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task.
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(6) Actions.
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Linux has a number of actions available that a subject may perform upon an
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object. The set of actions available depends on the nature of the subject
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and the object.
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Actions include reading, writing, creating and deleting files; forking or
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signalling and tracing tasks.
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(7) Rules, access control lists and security calculations.
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When a subject acts upon an object, a security calculation is made. This
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involves taking the subjective context, the objective context and the
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action, and searching one or more sets of rules to see whether the subject
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is granted or denied permission to act in the desired manner on the
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object, given those contexts.
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There are two main sources of rules:
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(a) Discretionary access control (DAC):
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Sometimes the object will include sets of rules as part of its
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description. This is an 'Access Control List' or 'ACL'. A Linux
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file may supply more than one ACL.
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A traditional UNIX file, for example, includes a permissions mask that
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is an abbreviated ACL with three fixed classes of subject ('user',
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'group' and 'other'), each of which may be granted certain privileges
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('read', 'write' and 'execute' - whatever those map to for the object
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in question). UNIX file permissions do not allow the arbitrary
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specification of subjects, however, and so are of limited use.
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A Linux file might also sport a POSIX ACL. This is a list of rules
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that grants various permissions to arbitrary subjects.
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(b) Mandatory access control (MAC):
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The system as a whole may have one or more sets of rules that get
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applied to all subjects and objects, regardless of their source.
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SELinux and Smack are examples of this.
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In the case of SELinux and Smack, each object is given a label as part
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of its credentials. When an action is requested, they take the
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subject label, the object label and the action and look for a rule
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that says that this action is either granted or denied.
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====================
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TYPES OF CREDENTIALS
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====================
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The Linux kernel supports the following types of credentials:
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(1) Traditional UNIX credentials.
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Real User ID
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Real Group ID
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The UID and GID are carried by most, if not all, Linux objects, even if in
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some cases it has to be invented (FAT or CIFS files for example, which are
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derived from Windows). These (mostly) define the objective context of
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that object, with tasks being slightly different in some cases.
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Effective, Saved and FS User ID
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Effective, Saved and FS Group ID
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Supplementary groups
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These are additional credentials used by tasks only. Usually, an
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EUID/EGID/GROUPS will be used as the subjective context, and real UID/GID
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will be used as the objective. For tasks, it should be noted that this is
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not always true.
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(2) Capabilities.
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Set of permitted capabilities
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Set of inheritable capabilities
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Set of effective capabilities
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Capability bounding set
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These are only carried by tasks. They indicate superior capabilities
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granted piecemeal to a task that an ordinary task wouldn't otherwise have.
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These are manipulated implicitly by changes to the traditional UNIX
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credentials, but can also be manipulated directly by the capset() system
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call.
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The permitted capabilities are those caps that the process might grant
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itself to its effective or permitted sets through capset(). This
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inheritable set might also be so constrained.
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The effective capabilities are the ones that a task is actually allowed to
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make use of itself.
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The inheritable capabilities are the ones that may get passed across
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execve().
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The bounding set limits the capabilities that may be inherited across
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execve(), especially when a binary is executed that will execute as UID 0.
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(3) Secure management flags (securebits).
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These are only carried by tasks. These govern the way the above
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credentials are manipulated and inherited over certain operations such as
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execve(). They aren't used directly as objective or subjective
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credentials.
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(4) Keys and keyrings.
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These are only carried by tasks. They carry and cache security tokens
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that don't fit into the other standard UNIX credentials. They are for
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making such things as network filesystem keys available to the file
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accesses performed by processes, without the necessity of ordinary
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programs having to know about security details involved.
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Keyrings are a special type of key. They carry sets of other keys and can
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be searched for the desired key. Each process may subscribe to a number
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of keyrings:
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Per-thread keying
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Per-process keyring
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Per-session keyring
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When a process accesses a key, if not already present, it will normally be
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cached on one of these keyrings for future accesses to find.
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For more information on using keys, see Documentation/keys.txt.
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(5) LSM
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The Linux Security Module allows extra controls to be placed over the
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operations that a task may do. Currently Linux supports two main
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alternate LSM options: SELinux and Smack.
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Both work by labelling the objects in a system and then applying sets of
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rules (policies) that say what operations a task with one label may do to
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an object with another label.
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(6) AF_KEY
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This is a socket-based approach to credential management for networking
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stacks [RFC 2367]. It isn't discussed by this document as it doesn't
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interact directly with task and file credentials; rather it keeps system
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level credentials.
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When a file is opened, part of the opening task's subjective context is
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recorded in the file struct created. This allows operations using that file
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struct to use those credentials instead of the subjective context of the task
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that issued the operation. An example of this would be a file opened on a
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network filesystem where the credentials of the opened file should be presented
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to the server, regardless of who is actually doing a read or a write upon it.
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=============
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FILE MARKINGS
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=============
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Files on disk or obtained over the network may have annotations that form the
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objective security context of that file. Depending on the type of filesystem,
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this may include one or more of the following:
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(*) UNIX UID, GID, mode;
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(*) Windows user ID;
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(*) Access control list;
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(*) LSM security label;
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(*) UNIX exec privilege escalation bits (SUID/SGID);
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(*) File capabilities exec privilege escalation bits.
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These are compared to the task's subjective security context, and certain
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operations allowed or disallowed as a result. In the case of execve(), the
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privilege escalation bits come into play, and may allow the resulting process
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extra privileges, based on the annotations on the executable file.
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================
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TASK CREDENTIALS
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================
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In Linux, all of a task's credentials are held in (uid, gid) or through
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(groups, keys, LSM security) a refcounted structure of type 'struct cred'.
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Each task points to its credentials by a pointer called 'cred' in its
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task_struct.
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Once a set of credentials has been prepared and committed, it may not be
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changed, barring the following exceptions:
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(1) its reference count may be changed;
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(2) the reference count on the group_info struct it points to may be changed;
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(3) the reference count on the security data it points to may be changed;
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(4) the reference count on any keyrings it points to may be changed;
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(5) any keyrings it points to may be revoked, expired or have their security
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attributes changed; and
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(6) the contents of any keyrings to which it points may be changed (the whole
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point of keyrings being a shared set of credentials, modifiable by anyone
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with appropriate access).
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To alter anything in the cred struct, the copy-and-replace principle must be
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adhered to. First take a copy, then alter the copy and then use RCU to change
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the task pointer to make it point to the new copy. There are wrappers to aid
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with this (see below).
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A task may only alter its _own_ credentials; it is no longer permitted for a
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task to alter another's credentials. This means the capset() system call is no
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longer permitted to take any PID other than the one of the current process.
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Also keyctl_instantiate() and keyctl_negate() functions no longer permit
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attachment to process-specific keyrings in the requesting process as the
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instantiating process may need to create them.
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IMMUTABLE CREDENTIALS
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---------------------
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Once a set of credentials has been made public (by calling commit_creds() for
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example), it must be considered immutable, barring two exceptions:
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(1) The reference count may be altered.
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(2) Whilst the keyring subscriptions of a set of credentials may not be
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changed, the keyrings subscribed to may have their contents altered.
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To catch accidental credential alteration at compile time, struct task_struct
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has _const_ pointers to its credential sets, as does struct file. Furthermore,
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certain functions such as get_cred() and put_cred() operate on const pointers,
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thus rendering casts unnecessary, but require to temporarily ditch the const
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qualification to be able to alter the reference count.
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ACCESSING TASK CREDENTIALS
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--------------------------
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A task being able to alter only its own credentials permits the current process
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to read or replace its own credentials without the need for any form of locking
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- which simplifies things greatly. It can just call:
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const struct cred *current_cred()
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to get a pointer to its credentials structure, and it doesn't have to release
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it afterwards.
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There are convenience wrappers for retrieving specific aspects of a task's
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credentials (the value is simply returned in each case):
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uid_t current_uid(void) Current's real UID
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gid_t current_gid(void) Current's real GID
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uid_t current_euid(void) Current's effective UID
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gid_t current_egid(void) Current's effective GID
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uid_t current_fsuid(void) Current's file access UID
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gid_t current_fsgid(void) Current's file access GID
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kernel_cap_t current_cap(void) Current's effective capabilities
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void *current_security(void) Current's LSM security pointer
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struct user_struct *current_user(void) Current's user account
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There are also convenience wrappers for retrieving specific associated pairs of
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a task's credentials:
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void current_uid_gid(uid_t *, gid_t *);
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void current_euid_egid(uid_t *, gid_t *);
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void current_fsuid_fsgid(uid_t *, gid_t *);
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which return these pairs of values through their arguments after retrieving
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them from the current task's credentials.
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In addition, there is a function for obtaining a reference on the current
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process's current set of credentials:
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const struct cred *get_current_cred(void);
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and functions for getting references to one of the credentials that don't
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actually live in struct cred:
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struct user_struct *get_current_user(void);
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struct group_info *get_current_groups(void);
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which get references to the current process's user accounting structure and
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supplementary groups list respectively.
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Once a reference has been obtained, it must be released with put_cred(),
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free_uid() or put_group_info() as appropriate.
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ACCESSING ANOTHER TASK'S CREDENTIALS
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------------------------------------
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Whilst a task may access its own credentials without the need for locking, the
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same is not true of a task wanting to access another task's credentials. It
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must use the RCU read lock and rcu_dereference().
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The rcu_dereference() is wrapped by:
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const struct cred *__task_cred(struct task_struct *task);
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This should be used inside the RCU read lock, as in the following example:
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void foo(struct task_struct *t, struct foo_data *f)
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{
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const struct cred *tcred;
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...
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rcu_read_lock();
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tcred = __task_cred(t);
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f->uid = tcred->uid;
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f->gid = tcred->gid;
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f->groups = get_group_info(tcred->groups);
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rcu_read_unlock();
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...
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}
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A function need not get RCU read lock to use __task_cred() if it is holding a
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spinlock at the time as this implicitly holds the RCU read lock.
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Should it be necessary to hold another task's credentials for a long period of
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time, and possibly to sleep whilst doing so, then the caller should get a
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reference on them using:
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const struct cred *get_task_cred(struct task_struct *task);
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This does all the RCU magic inside of it. The caller must call put_cred() on
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the credentials so obtained when they're finished with.
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There are a couple of convenience functions to access bits of another task's
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credentials, hiding the RCU magic from the caller:
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uid_t task_uid(task) Task's real UID
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uid_t task_euid(task) Task's effective UID
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If the caller is holding a spinlock or the RCU read lock at the time anyway,
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then:
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__task_cred(task)->uid
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__task_cred(task)->euid
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should be used instead. Similarly, if multiple aspects of a task's credentials
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need to be accessed, RCU read lock or a spinlock should be used, __task_cred()
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called, the result stored in a temporary pointer and then the credential
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aspects called from that before dropping the lock. This prevents the
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potentially expensive RCU magic from being invoked multiple times.
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Should some other single aspect of another task's credentials need to be
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accessed, then this can be used:
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task_cred_xxx(task, member)
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where 'member' is a non-pointer member of the cred struct. For instance:
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uid_t task_cred_xxx(task, suid);
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will retrieve 'struct cred::suid' from the task, doing the appropriate RCU
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magic. This may not be used for pointer members as what they point to may
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disappear the moment the RCU read lock is dropped.
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ALTERING CREDENTIALS
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--------------------
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As previously mentioned, a task may only alter its own credentials, and may not
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alter those of another task. This means that it doesn't need to use any
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locking to alter its own credentials.
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To alter the current process's credentials, a function should first prepare a
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new set of credentials by calling:
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struct cred *prepare_creds(void);
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this locks current->cred_replace_mutex and then allocates and constructs a
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duplicate of the current process's credentials, returning with the mutex still
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held if successful. It returns NULL if not successful (out of memory).
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The mutex prevents ptrace() from altering the ptrace state of a process whilst
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security checks on credentials construction and changing is taking place as
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the ptrace state may alter the outcome, particularly in the case of execve().
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The new credentials set should be altered appropriately, and any security
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checks and hooks done. Both the current and the proposed sets of credentials
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are available for this purpose as current_cred() will return the current set
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still at this point.
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When the credential set is ready, it should be committed to the current process
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by calling:
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int commit_creds(struct cred *new);
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This will alter various aspects of the credentials and the process, giving the
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LSM a chance to do likewise, then it will use rcu_assign_pointer() to actually
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commit the new credentials to current->cred, it will release
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current->cred_replace_mutex to allow ptrace() to take place, and it will notify
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the scheduler and others of the changes.
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This function is guaranteed to return 0, so that it can be tail-called at the
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end of such functions as sys_setresuid().
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Note that this function consumes the caller's reference to the new credentials.
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The caller should _not_ call put_cred() on the new credentials afterwards.
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Furthermore, once this function has been called on a new set of credentials,
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those credentials may _not_ be changed further.
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Should the security checks fail or some other error occur after prepare_creds()
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has been called, then the following function should be invoked:
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void abort_creds(struct cred *new);
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This releases the lock on current->cred_replace_mutex that prepare_creds() got
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and then releases the new credentials.
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A typical credentials alteration function would look something like this:
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int alter_suid(uid_t suid)
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{
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struct cred *new;
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int ret;
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new = prepare_creds();
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if (!new)
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return -ENOMEM;
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new->suid = suid;
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ret = security_alter_suid(new);
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if (ret < 0) {
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abort_creds(new);
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return ret;
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}
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return commit_creds(new);
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}
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MANAGING CREDENTIALS
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--------------------
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There are some functions to help manage credentials:
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(*) void put_cred(const struct cred *cred);
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This releases a reference to the given set of credentials. If the
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reference count reaches zero, the credentials will be scheduled for
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destruction by the RCU system.
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(*) const struct cred *get_cred(const struct cred *cred);
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This gets a reference on a live set of credentials, returning a pointer to
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that set of credentials.
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(*) struct cred *get_new_cred(struct cred *cred);
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This gets a reference on a set of credentials that is under construction
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and is thus still mutable, returning a pointer to that set of credentials.
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=====================
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|
OPEN FILE CREDENTIALS
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|
=====================
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When a new file is opened, a reference is obtained on the opening task's
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|
credentials and this is attached to the file struct as 'f_cred' in place of
|
|
'f_uid' and 'f_gid'. Code that used to access file->f_uid and file->f_gid
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|
should now access file->f_cred->fsuid and file->f_cred->fsgid.
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|
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It is safe to access f_cred without the use of RCU or locking because the
|
|
pointer will not change over the lifetime of the file struct, and nor will the
|
|
contents of the cred struct pointed to, barring the exceptions listed above
|
|
(see the Task Credentials section).
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|
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|
=======================================
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|
OVERRIDING THE VFS'S USE OF CREDENTIALS
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|
=======================================
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Under some circumstances it is desirable to override the credentials used by
|
|
the VFS, and that can be done by calling into such as vfs_mkdir() with a
|
|
different set of credentials. This is done in the following places:
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|
|
(*) sys_faccessat().
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|
|
(*) do_coredump().
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|
|
(*) nfs4recover.c.
|