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264 lines
12 KiB
Text
This is the Linux kernel capabilities FAQ
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Its history, to the extent that I am able to reconstruct it is that
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v2.0 was posted to the Linux kernel list on 1999/04/02 by Boris
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Tobotras. Thanks to Denis Ducamp for forwarding me a copy.
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Cheers
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Andrew
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Linux Capabilities FAQ 0.2
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==========================
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1) What is a capability?
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The name "capabilities" as used in the Linux kernel can be confusing.
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First there are Capabilities as defined in computer science. A
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capability is a token used by a process to prove that it is allowed to
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do an operation on an object. The capability identifies the object
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and the operations allowed on that object. A file descriptor is a
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capability. You create the file descriptor with the "open" call and
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request read or write permissions. Later, when doing a read or write
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operation, the kernel uses the file descriptor as an index into a
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data structure that indicates what operations are allowed. This is an
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efficient way to check permissions. The necessary data structures are
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created once during the "open" call. Later read and write calls only
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have to do a table lookup. Operations on capabilities include copying
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capabilities, transferring capabilities between processes, modifying a
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capability, and revoking a capability. Modifying a capability can be
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something like taking a read-write filedescriptor and making it
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read-only. A capability often has a notion of an "owner" which is
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able to invalidate all copies and derived versions of a capability.
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Entire OSes are based on this "capability" model, with varying degrees
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of purity. There are other ways of implementing capabilities than the
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file descriptor model - traditionally special hardware has been used,
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but modern systems also use the memory management unit of the CPU.
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Then there is something quite different called "POSIX capabilities"
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which is what Linux uses. These capabilities are a partitioning of
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the all powerful root privilege into a set of distinct privileges (but
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look at securelevel emulation to find out that this isn't necessary
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the whole truth). Users familiar with VMS or "Trusted" versions of
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other UNIX variants will know this under the name "privileges". The
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name "capabilities" comes from the now defunct POSIX draft 1003.1e
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which used this name.
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2) So what is a "POSIX capability"?
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A process has three sets of bitmaps called the inheritable(I),
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permitted(P), and effective(E) capabilities. Each capability is
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implemented as a bit in each of these bitmaps which is either set or
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unset. When a process tries to do a privileged operation, the
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operating system will check the appropriate bit in the effective set
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of the process (instead of checking whether the effective uid of the
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process i 0 as is normally done). For example, when a process tries
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to set the clock, the Linux kernel will check that the process has the
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CAP_SYS_TIME bit (which is currently bit 25) set in its effective set.
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The permitted set of the process indicates the capabilities the
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process can use. The process can have capabilities set in the
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permitted set that are not in the effective set. This indicates that
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the process has temporarily disabled this capability. A process is
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allowed to set a bit in its effective set only if it is available in
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the permitted set. The distinction between effective and permitted
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exists so that processes can "bracket" operations that need privilege.
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The inheritable capabilities are the capabilities of the current
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process that should be inherited by a program executed by the current
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process. The permitted set of a process is masked against the
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inheritable set during exec(). Nothing special happens during fork()
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or clone(). Child processes and threads are given an exact copy of
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the capabilities of the parent process.
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3) What about other entities in the system? Users, Groups, Files?
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Files have capabilities. Conceptually they have the same three
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bitmaps that processes have, but to avoid confusion we call them by
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other names. Only executable files have capabilities, libraries don't
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have capabilities (yet). The three sets are called the allowed set,
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the forced set, and the effective set.
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The allowed set indicates what capabilities the executable is allowed
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to receive from an execing process. This means that during exec(),
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the capabilities of the old process are first masked against a set
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which indicates what the process gives away (the inheritable set of
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the process), and then they are masked against a set which indicates
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what capabilities the new process image is allowed to receive (the
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allowed set of the executable).
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The forced set is a set of capabilities created out of thin air and
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given to the process after execing the executable. The forced set is
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similar in nature to the setuid feature. In fact, the setuid bit from
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the filesystem is "read" as a full forced set by the kernel.
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The effective set indicates which bits in the permitted set of the new
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process should be transferred to the effective set of the new process.
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The effective set is best thought of as a "capability aware" set. It
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should consist of only 1s if the executable is capability-dumb, or
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only 0s if the executable is capability-smart. Since the effective
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set consists of only 0s or only 1s, the filesystem can implement this
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set using a single bit.
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NOTE: Filesystem support for capabilities is not part of Linux 2.2.
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Users and Groups don't have associated capabilities from the kernel's
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point of view, but it is entirely reasonable to associate users or
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groups with capabilities. By letting the "login" program set some
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capabilities it is possible to make role users such as a backup user
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that will have the CAP_DAC_READ_SEARCH capability and be able to do
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backups. This could also be implemented as a PAM module, but nobody
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has implemented one yet.
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4) What capabilities exist?
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The capabilities available in Linux are listed and documented in the
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file /usr/src/linux/include/linux/capability.h.
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5) Are Linux capabilities hierarchical?
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No, you cannot make a "subcapability" out of a Linux capability as in
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capability-based OSes.
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6) How can I use capabilities to make sure Mr. Evil Luser (eluser)
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can't exploit my "suid" programs?
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This is the general outline of how this works given filesystem
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capability support exists. First, you have a PAM module that sets the
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inheritable capabilities of the login-shell of eluser. Then for all
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"suid" programs on the system, you decide what capabilities they need
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and set the _allowed_ set of the executable to that set of
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capabilities. The capability rules
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new permitted = forced | (allowed & inheritable)
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means that you should be careful about setting forced capabilities on
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executables. In a few cases, this can be useful though. For example
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the login program needs to set the inheritable set of the new user and
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therefore needs an almost full permitted set. So if you want eluser
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to be able to run login and log in as a different user, you will have
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to set some forced bits on that executable.
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7) What about passing capabilities between processes?
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Currently this is done by the system call "setcap" which can set the
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capabilities of another process. This requires the CAP_SETPCAP
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capability which you really only want to grant a _few_ processes.
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CAP_SETPCAP was originally intended as a workaround to be able to
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implement filesystem support for capabilities using a daemon outside
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the kernel.
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There has been discussions about implementing socket-level capability
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passing. This means that you can pass a capability over a socket. No
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support for this exists in the official kernel yet.
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8) I see securelevel has been removed from 2.2 and are superceeded by
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capabilities. How do I emulate securelevel using capabilities?
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The setcap system call can remove a capability from _all_ processes on
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the system in one atomic operation. The setcap utility from the
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libcap distribution will do this for you. The utility requires the
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CAP_SETPCAP privilege to do this. The CAP_SETPCAP capability is not
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enabled by default.
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libcap is available from
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ftp://ftp.kernel.org/pub/linux/libs/security/linux-privs/kernel-2.2/
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9) I noticed that the capability.h file lacks some capabilities that
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are needed to fully emulate 2.0 securelevel. Is there a patch for
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this?
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Actually yes - funny you should ask :-). The problem with 2.0
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securelevel is that they for example stop root from accessing block
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devices. At the same time they restrict the use of iopl. These two
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changes are fundamentally different. Blocking access to block devices
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means restricting something that usually isn't restricted.
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Restricting access to the use of iopl on the other hand means
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restricting (blocking) access to something that is already blocked.
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Emulating the parts of 2.0 securelevel that restricts things that are
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normally not restricted means that the capabilites in the kernel has
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to have a set of capabilities that are usually _on_ for a normal
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process (note that this breaks the explanation that capabilities are a
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partitioning of the root privileges). There is an experimental patch at
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ftp://ftp.guardian.no/pub/free/linux/capabilities/patch-cap-exp-1
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which implements a set of capabilities with the "CAP_USER" prefix:
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cap_user_sock - allowed to use socket()
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cap_user_dev - allowed to open char/block devices
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cap_user_fifo - allowed to use pipes
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These should be enough to emulate 2.0 securelevel (tell me if we need
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something more).
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10) Seems I need a CAP_SETPCAP capability that I don't have to make use
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of capabilities. How do I enable this capability?
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Change the definition of CAP_INIT_EFF_SET and CAP_INIT_INH_SET to the
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following in include/linux/capability.h:
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#define CAP_INIT_EFF_SET { ~0 }
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#define CAP_INIT_INH_SET { ~0 }
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This will start init with a full capability set and not with
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CAP_SETPCAP removed.
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11) How do I start a process with a limited set of capabilities?
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Get the libcap library and use the execcap utility. The following
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example starts the update daemon with only the CAP_SYS_ADMIN
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capability.
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execcap 'cap_sys_admin=eip' update
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12) How do I start a process with a limited set of capabilities under
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another uid?
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Use the sucap utility which changes uid from root without loosing any
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capabilities. Normally all capabilities are cleared when changing uid
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from root. The sucap utility requires the CAP_SETPCAP capability.
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The following example starts updated under uid updated and gid updated
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with CAP_SYS_ADMIN raised in the Effective set.
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sucap updated updated execcap 'cap_sys_admin=eip' update
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[ Sucap is currently available from
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ftp://ftp.guardian.no/pub/free/linux/capabilities/sucap.c. Put it in
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the progs directory of libcap to compile.]
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13) What are the "capability rules"
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The capability rules are the rules used to set the capabilities of the
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new process image after an exec. They work like this:
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pI' = pI
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(***) pP' = fP | (fI & pI)
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pE' = pP' & fE [NB. fE is 0 or ~0]
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I=Inheritable, P=Permitted, E=Effective // p=process, f=file
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' indicates post-exec().
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Now to make sense of the equations think of fP as the Forced set of
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the executable, and fI as the Allowed set of the executable. Notice
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how the Inheritable set isn't touched at all during exec().
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14) What are the laws for setting capability bits in the Inheritable,
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Permitted, and Effective sets?
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Bits can be transferred from Permitted to either Effective or
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Inheritable set.
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Bits can be removed from all sets.
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15) Where is the standard on which the Linux capabilities are based?
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There used to be a POSIX draft called POSIX.6 and later POSIX 1003.1e.
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However after the committee had spent over 10 years, POSIX decided
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that enough is enough and dropped the draft. There will therefore not
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be a POSIX standard covering security anytime soon. This may lead to
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that the POSIX draft is available for free, however.
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--
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Best regards, -- Boris.
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