SUDOERS(5) | File Formats Manual | SUDOERS(5) |
sudoers
— default
sudo security policy plugin
The sudoers
policy plugin determines a
user's sudo
privileges. It is the default
sudo
policy plugin. The policy is driven by the
/etc/sudoers file or, optionally in LDAP. The policy
format is described in detail in the
SUDOERS FILE FORMAT section.
For information on storing sudoers
policy
information in LDAP, please see sudoers.ldap(5).
sudo
consults the
sudo.conf(5) file to determine which policy and I/O
logging plugins to load. If no sudo.conf(5) file is
present, or if it contains no Plugin
lines,
sudoers
will be used for policy decisions and I/O
logging. To explicitly configure sudo.conf(5) to use the
sudoers
plugin, the following configuration can be
used.
Plugin sudoers_policy sudoers.so Plugin sudoers_io sudoers.so
Starting with sudo
1.8.5, it is possible
to specify optional arguments to the sudoers
plugin
in the sudo.conf(5) file. These arguments, if present,
should be listed after the path to the plugin (i.e., after
sudoers.so). Multiple arguments may be specified,
separated by white space. For example:
Plugin sudoers_policy sudoers.so sudoers_mode=0400
The following plugin arguments are supported:
For more information on configuring sudo.conf(5), please refer to its manual.
The sudoers
security policy requires that
most users authenticate themselves before they can use
sudo
. A password is not required if the invoking
user is root, if the target user is the same as the invoking user, or if the
policy has disabled authentication for the user or command. Unlike
su(1), when sudoers
requires
authentication, it validates the invoking user's credentials, not the target
user's (or root's) credentials. This can be changed via the
rootpw, targetpw and
runaspw flags, described later.
If a user who is not listed in the policy tries to run a command
via sudo
, mail is sent to the proper authorities.
The address used for such mail is configurable via the
mailto Defaults entry (described later) and defaults to
root
.
Note that no mail will be sent if an unauthorized user tries to
run sudo
with the -l
or
-v
option unless there is an authentication error
and either the mail_always or
mail_badpass flags are enabled. This allows users to
determine for themselves whether or not they are allowed to use
sudo
. All attempts to run
sudo
(successful or not) will be logged, regardless
of whether or not mail is sent.
If sudo
is run by root and the
SUDO_USER
environment variable is set, the
sudoers
policy will use this value to determine who
the actual user is. This can be used by a user to log commands through sudo
even when a root shell has been invoked. It also allows the
-e
option to remain useful even when invoked via a
sudo-run script or program. Note, however, that the
sudoers file lookup is still done for root, not the user
specified by SUDO_USER
.
sudoers
uses per-user time stamp files for
credential caching. Once a user has been authenticated, a record is written
containing the user ID that was used to authenticate, the terminal session
ID, the start time of the session leader (or parent process) and a time
stamp (using a monotonic clock if one is available). The user may then use
sudo
without a password for a short period of time
(15
minutes unless overridden by the
timestamp_timeout option). By default,
sudoers
uses a separate record for each terminal,
which means that a user's login sessions are authenticated separately. The
timestamp_type option can be used to select the type of
time stamp record sudoers
will use.
sudoers
can log both successful and
unsuccessful attempts (as well as errors) to syslog(3), a
log file, or both. By default, sudoers
will log via
syslog(3) but this is changeable via the
syslog and logfile Defaults settings.
See LOG FORMAT for a description of the
log file format.
sudoers
is also capable of running a
command in a pseudo-tty and logging all input and/or output. The standard
input, standard output and standard error can be logged even when not
associated with a terminal. I/O logging is not on by default but can be
enabled using the log_input and
log_output options as well as the
LOG_INPUT
and LOG_OUTPUT
command tags. See I/O LOG FILES for
details on how I/O log files are stored.
Since environment variables can influence program behavior,
sudoers
provides a means to restrict which variables
from the user's environment are inherited by the command to be run. There
are two distinct ways sudoers
can deal with
environment variables.
By default, the env_reset option is enabled.
This causes commands to be executed with a new, minimal environment. On AIX
(and Linux systems without PAM), the environment is initialized with the
contents of the /etc/environment file. The new
environment contains the TERM
,
PATH
, HOME
,
MAIL
, SHELL
,
LOGNAME
, USER
and
SUDO_*
variables in addition to variables from the
invoking process permitted by the env_check and
env_keep options. This is effectively a whitelist for
environment variables. The environment variables
LOGNAME
and USER
are treated
specially. If one of them is preserved (or removed) from user's environment,
the other will be as well. If LOGNAME
and
USER
are to be preserved but only one of them is
present in the user's environment, the other will be set to the same value.
This avoids an inconsistent environment where one of the variables
describing the user name is set to the invoking user and one is set to the
target user. ()
are removed unless both the name and
value parts are matched by env_keep or
env_check, as they may be interpreted as functions by the
bash shell. Prior to version 1.8.11, such variables were
always removed.
If, however, the env_reset option is disabled,
any variables not explicitly denied by the env_check and
env_delete options are inherited from the invoking
process. In this case, env_check and
env_delete behave like a blacklist. Prior to version
1.8.21, environment variables with a value beginning with
()
were always removed. Beginning with version
1.8.21, a pattern in env_delete is used to match
bash shell functions instead. Since it is not possible to
blacklist all potentially dangerous environment variables, use of the
default env_reset behavior is encouraged.
Environment variables specified by env_check,
env_delete, or env_keep may include one
or more ‘*
’ characters which will
match zero or more characters. No other wildcard characters are
supported.
By default, environment variables are matched by name. However, if
the pattern includes an equal sign
(‘=
’), both the variables name and
value must match. For example, a bash shell function could
be matched as follows:
env_keep += "BASH_FUNC_my_func%%=()*"
Without the “=()*
” suffix,
this would not match, as bash shell functions are not
preserved by default.
The complete list of environment variables that
sudo
allows or denies is contained in the output of
“sudo -V
” when run as root. Please
note that this list varies based on the operating system
sudo
is running on.
On systems that support PAM where the
pam_env module is
enabled for sudo
, variables in the PAM environment
may be merged in to the environment. If a variable in the PAM environment is
already present in the user's environment, the value will only be overridden
if the variable was not preserved by sudoers
. When
env_reset is enabled, variables preserved from the
invoking user's environment by the env_keep list take
precedence over those in the PAM environment. When
env_reset is disabled, variables present the invoking
user's environment take precedence over those in the PAM environment unless
they match a pattern in the env_delete list.
Note that the dynamic linker on most operating systems will remove
variables that can control dynamic linking from the environment of setuid
executables, including sudo
. Depending on the
operating system this may include _RLD*
,
DYLD_*
, LD_*
,
LDR_*
, LIBPATH
,
SHLIB_PATH
, and others. These type of variables are
removed from the environment before sudo
even begins
execution and, as such, it is not possible for sudo
to preserve them.
As a special case, if sudo
's
-i
option (initial login) is specified,
sudoers
will initialize the environment regardless
of the value of env_reset. The
DISPLAY
, PATH
and
TERM
variables remain unchanged;
HOME
, MAIL
,
SHELL
, USER
, and
LOGNAME
are set based on the target user. On AIX
(and Linux systems without PAM), the contents of
/etc/environment are also included. All other
environment variables are removed unless permitted by
env_keep or env_check, described
above.
Finally, the restricted_env_file and env_file files are applied, if present. The variables in restricted_env_file are applied first and are subject to the same restrictions as the invoking user's environment, as detailed above. The variables in env_file are applied last and are not subject to these restrictions. In both cases, variables present in the files will only be set to their specified values if they would not conflict with an existing environment variable.
The sudoers file is composed of two types of entries: aliases (basically variables) and user specifications (which specify who may run what).
When multiple entries match for a user, they are applied in order. Where there are multiple matches, the last match is used (which is not necessarily the most specific match).
The sudoers file grammar will be described below in Extended Backus-Naur Form (EBNF). Don't despair if you are unfamiliar with EBNF; it is fairly simple, and the definitions below are annotated.
EBNF is a concise and exact way of describing the grammar of a language. Each EBNF definition is made up of production rules. E.g.,
symbol ::= definition
|
alternate1
| alternate2
...
Each production rule references others and thus makes up a grammar for the language. EBNF also contains the following operators, which many readers will recognize from regular expressions. Do not, however, confuse them with “wildcard” characters, which have different meanings.
?
*
+
Parentheses may be used to group symbols together. For clarity, we will use single quotes ('') to designate what is a verbatim character string (as opposed to a symbol name).
There are four kinds of aliases:
User_Alias
, Runas_Alias
,
Host_Alias
and
Cmnd_Alias
.
Alias ::= 'User_Alias' User_Alias_Spec (':' User_Alias_Spec)* | 'Runas_Alias' Runas_Alias_Spec (':' Runas_Alias_Spec)* | 'Host_Alias' Host_Alias_Spec (':' Host_Alias_Spec)* | 'Cmnd_Alias' Cmnd_Alias_Spec (':' Cmnd_Alias_Spec)* User_Alias ::= NAME User_Alias_Spec ::= User_Alias '=' User_List Runas_Alias ::= NAME Runas_Alias_Spec ::= Runas_Alias '=' Runas_List Host_Alias ::= NAME Host_Alias_Spec ::= Host_Alias '=' Host_List Cmnd_Alias ::= NAME Cmnd_Alias_Spec ::= Cmnd_Alias '=' Cmnd_List NAME ::= [A-Z]([A-Z][0-9]_)*
Each alias definition is of the form
Alias_Type NAME = item1, item2, ...
where
Alias_Type is
one of User_Alias
,
Runas_Alias
, Host_Alias
, or
Cmnd_Alias
. A NAME
is a
string of uppercase letters, numbers, and underscore characters
(‘_
’). A NAME
must start
with an uppercase letter. It is possible to put several alias definitions of
the same type on a single line, joined by a colon
(‘:
’). E.g.,
Alias_Type NAME = item1, item2, item3 : NAME = item4, item5
It is a syntax error to redefine an existing alias. It is possible to use the same name for aliases of different types, but this is not recommended.
The definitions of what constitutes a valid alias member follow.
User_List ::= User | User ',' User_List User ::= '!'* user name | '!'* #uid | '!'* %group | '!'* %#gid | '!'* +netgroup | '!'* %:nonunix_group | '!'* %:#nonunix_gid | '!'* User_Alias
A User_List
is made up of one or more user
names, user IDs (prefixed with ‘#
’),
system group names and IDs (prefixed with
‘%
’ and
‘%#
’ respectively), netgroups
(prefixed with ‘+
’), non-Unix group
names and IDs (prefixed with ‘%:
’ and
‘%:#
’ respectively) and
User_Alias
es. Each list item may be prefixed with
zero or more ‘!
’ operators. An odd
number of ‘!
’ operators negate the
value of the item; an even number just cancel each other out. User netgroups
are matched using the user and domain members only; the host member is not
used when matching.
A user name
, uid
,
group
, gid
,
netgroup
, nonunix_group
or
nonunix_gid
may be enclosed in double quotes to
avoid the need for escaping special characters. Alternately, special
characters may be specified in escaped hex mode, e.g., \x20 for space. When
using double quotes, any prefix characters must be included inside the
quotes.
The actual nonunix_group
and
nonunix_gid
syntax depends on the underlying group
provider plugin. For instance, the QAS AD plugin supports the following
formats:
See GROUP PROVIDER PLUGINS for more information.
Note that quotes around group names are optional. Unquoted strings
must use a backslash (‘\
’) to escape
spaces and special characters. See
Other
special characters and reserved words for a list of characters that need
to be escaped.
Runas_List ::= Runas_Member | Runas_Member ',' Runas_List Runas_Member ::= '!'* user name | '!'* #uid | '!'* %group | '!'* %#gid | '!'* %:nonunix_group | '!'* %:#nonunix_gid | '!'* +netgroup | '!'* Runas_Alias
A Runas_List
is similar to a
User_List
except that instead of
User_Alias
es it can contain
Runas_Alias
es. Note that user names and groups are
matched as strings. In other words, two users (groups) with the same uid
(gid) are considered to be distinct. If you wish to match all user names
with the same uid (e.g., root and toor), you can use a uid instead (#0 in
the example given).
Host_List ::= Host | Host ',' Host_List Host ::= '!'* host name | '!'* ip_addr | '!'* network(/netmask)? | '!'* +netgroup | '!'* Host_Alias
A Host_List
is made up of one or more host
names, IP addresses, network numbers, netgroups (prefixed with
‘+
’) and other aliases. Again, the
value of an item may be negated with the
‘!
’ operator. Host netgroups are
matched using the host (both qualified and unqualified) and domain members
only; the user member is not used when matching. If you specify a network
number without a netmask, sudo
will query each of
the local host's network interfaces and, if the network number corresponds
to one of the hosts's network interfaces, will use the netmask of that
interface. The netmask may be specified either in standard IP address
notation (e.g., 255.255.255.0 or ffff:ffff:ffff:ffff::), or CIDR notation
(number of bits, e.g., 24 or 64). A host name may include shell-style
wildcards (see the Wildcards section
below), but unless the host name
command on your
machine returns the fully qualified host name, you'll need to use the
fqdn option for wildcards to be useful. Note that
sudo
only inspects actual network interfaces; this
means that IP address 127.0.0.1 (localhost) will never match. Also, the host
name “localhost” will only match if that is the actual host
name, which is usually only the case for non-networked systems.
digest ::= [A-Fa-f0-9]+ | [[A-Za-z0-9+/=]+ Digest_Spec ::= "sha224" ':' digest | "sha256" ':' digest | "sha384" ':' digest | "sha512" ':' digest Cmnd_List ::= Cmnd | Cmnd ',' Cmnd_List command name ::= file name | file name args | file name '""' Cmnd ::= Digest_Spec? '!'* command name | '!'* directory | '!'* "sudoedit" | '!'* Cmnd_Alias
A Cmnd_List
is a list of one
or more command names, directories, and other aliases. A command name is a
fully qualified file name which may include shell-style wildcards (see the
Wildcards section below). A simple file
name allows the user to run the command with any arguments he/she wishes.
However, you may also specify command line arguments (including wildcards).
Alternately, you can specify ""
to
indicate that the command may only be run
without command
line arguments. A directory is a fully qualified path name ending in a
‘/
’. When you specify a directory in a
Cmnd_List
, the user will be able to run any file
within that directory (but not in any sub-directories therein).
If a Cmnd
has associated command line
arguments, then the arguments in the Cmnd
must match
exactly those given by the user on the command line (or match the wildcards
if there are any). Note that the following characters must be escaped with a
‘\
’ if they are used in command
arguments: ‘,
’,
‘:
’,
‘=
’,
‘\
’. The built-in command
“sudoedit
” is used to permit a user to
run sudo
with the -e
option
(or as sudoedit
). It may take command line arguments
just as a normal command does. Note that
“sudoedit
” is a command built into
sudo
itself and must be specified in the
sudoers file without a leading path.
If a command name
is prefixed with a
Digest_Spec
, the command will only match
successfully if it can be verified using the specified SHA-2 digest. The
following digest formats are supported: sha224, sha256, sha384 and sha512.
The string may be specified in either hex or base64 format (base64 is more
compact). There are several utilities capable of generating SHA-2 digests in
hex format such as openssl, shasum, sha224sum, sha256sum, sha384sum,
sha512sum.
For example, using openssl:
$ openssl dgst -sha224 /bin/ls SHA224(/bin/ls)= 118187da8364d490b4a7debbf483004e8f3e053ec954309de2c41a25
It is also possible to use openssl to generate base64 output:
$ openssl dgst -binary -sha224 /bin/ls | openssl base64 EYGH2oNk1JC0p9679IMATo8+BT7JVDCd4sQaJQ==
Warning, if the user has write access to the command itself
(directly or via a sudo
command), it may be possible
for the user to replace the command after the digest check has been
performed but before the command is executed. A similar race condition
exists on systems that lack the fexecve(2) system call
when the directory in which the command is located is writable by the user.
See the description of the fdexec setting for more
information on how sudo
executes commands that have
an associated digest.
Command digests are only supported by version 1.8.7 or higher.
Certain configuration options may be changed from their default
values at run-time via one or more Default_Entry
lines. These may affect all users on any host, all users on a specific host,
a specific user, a specific command, or commands being run as a specific
user. Note that per-command entries may not include command line arguments.
If you need to specify arguments, define a
Cmnd_Alias
and reference that instead.
Default_Type ::= 'Defaults' | 'Defaults' '@' Host_List | 'Defaults' ':' User_List | 'Defaults' '!' Cmnd_List | 'Defaults' '>' Runas_List Default_Entry ::= Default_Type Parameter_List Parameter_List ::= Parameter | Parameter ',' Parameter_List Parameter ::= Parameter '=' Value | Parameter '+=' Value | Parameter '-=' Value | '!'* Parameter
Parameters may be
flags,
integer
values,
strings,
or
lists.
Flags are implicitly boolean and can be turned off via the
‘!
’ operator. Some integer, string and
list parameters may also be used in a boolean context to disable them.
Values may be enclosed in double quotes ("") when they contain
multiple words. Special characters may be escaped with a backslash
(‘\
’).
Lists have two additional assignment operators,
+=
and -=
. These operators
are used to add to and delete from a list respectively. It is not an error
to use the -=
operator to remove an element that
does not exist in a list.
Defaults entries are parsed in the following order: generic, host, user and runas Defaults first, then command defaults. If there are multiple Defaults settings of the same type, the last matching setting is used. The following Defaults settings are parsed before all others since they may affect subsequent entries: fqdn, group_plugin, runas_default, sudoers_locale.
See SUDOERS OPTIONS for a list of supported Defaults parameters.
User_Spec ::= User_List Host_List '=' Cmnd_Spec_List \ (':' Host_List '=' Cmnd_Spec_List)* Cmnd_Spec_List ::= Cmnd_Spec | Cmnd_Spec ',' Cmnd_Spec_List Cmnd_Spec ::= Runas_Spec? Option_Spec* Tag_Spec* Cmnd Runas_Spec ::= '(' Runas_List? (':' Runas_List)? ')' Option_Spec ::= (SELinux_Spec | Date_Spec | Timeout_Spec) SELinux_Spec ::= ('ROLE=role' | 'TYPE=type') Date_Spec ::= ('NOTBEFORE=timestamp' | 'NOTAFTER=timestamp') Timeout_Spec ::= 'TIMEOUT=timeout' Tag_Spec ::= ('EXEC:' | 'NOEXEC:' | 'FOLLOW:' | 'NOFOLLOW' | 'LOG_INPUT:' | 'NOLOG_INPUT:' | 'LOG_OUTPUT:' | 'NOLOG_OUTPUT:' | 'MAIL:' | 'NOMAIL:' | 'PASSWD:' | 'NOPASSWD:' | 'SETENV:' | 'NOSETENV:')
A user specification determines which commands a user may run (and as what user) on specified hosts. By default, commands are run as root, but this can be changed on a per-command basis.
The basic structure of a user specification is “who where = (as_whom) what”. Let's break that down into its constituent parts:
A Runas_Spec
determines the user and/or
the group that a command may be run as. A fully-specified
Runas_Spec
consists of two
Runas_List
s (as defined above) separated by a colon
(‘:
’) and enclosed in a set of
parentheses. The first Runas_List
indicates which
users the command may be run as via sudo
's
-u
option. The second defines a list of groups that
can be specified via sudo
's
-g
option in addition to any of the target user's
groups. If both Runas_List
s are specified, the
command may be run with any combination of users and groups listed in their
respective Runas_List
s. If only the first is
specified, the command may be run as any user in the list but no
-g
option may be specified. If the first
Runas_List
is empty but the second is specified, the
command may be run as the invoking user with the group set to any listed in
the Runas_List
. If both
Runas_List
s are empty, the command may only be run
as the invoking user. If no Runas_Spec
is specified
the command may be run as root and no group may be
specified.
A Runas_Spec
sets the default for the
commands that follow it. What this means is that for the entry:
dgb boulder = (operator) /bin/ls, /bin/kill, /usr/bin/lprm
The user dgb may run /bin/ls, /bin/kill, and /usr/bin/lprm on the host boulder—but only as operator. E.g.,
$ sudo -u operator /bin/ls
It is also possible to override a
Runas_Spec
later on in an entry. If we modify the
entry like so:
dgb boulder = (operator) /bin/ls, (root) /bin/kill, /usr/bin/lprm
Then user dgb is now allowed to run /bin/ls as operator, but /bin/kill and /usr/bin/lprm as root.
We can extend this to allow dgb to run
/bin/ls
with either the user or group set to
operator:
dgb boulder = (operator : operator) /bin/ls, (root) /bin/kill,\ /usr/bin/lprm
Note that while the group portion of the
Runas_Spec
permits the user to run as command with
that group, it does not force the user to do so. If no group is specified on
the command line, the command will run with the group listed in the target
user's password database entry. The following would all be permitted by the
sudoers entry above:
$ sudo -u operator /bin/ls $ sudo -u operator -g operator /bin/ls $ sudo -g operator /bin/ls
In the following example, user tcm may run commands that access a modem device file with the dialer group.
tcm boulder = (:dialer) /usr/bin/tip, /usr/bin/cu,\ /usr/local/bin/minicom
Note that in this example only the group will be set, the command still runs as user tcm. E.g.
$ sudo -g dialer /usr/bin/cu
Multiple users and groups may be present in a
Runas_Spec
, in which case the user may select any
combination of users and groups via the -u
and
-g
options. In this example:
alan ALL = (root, bin : operator, system) ALL
user alan may run any command as either user root or bin, optionally setting the group to operator or system.
A Cmnd
may have zero or more options
associated with it. Options may consist of SELinux roles and/or types, start
and/or end dates and command timeouts. Once an option is set for a
Cmnd
, subsequent Cmnd
s in
the Cmnd_Spec_List
, inherit that option unless it is
overridden by another option.
On systems with SELinux support, sudoers file entries may optionally have an SELinux role and/or type associated with a command. If a role or type is specified with the command it will override any default values specified in sudoers. A role or type specified on the command line, however, will supersede the values in sudoers.
sudoers
rules can be specified with a
start and end date via the NOTBEFORE
and
NOTAFTER
settings. The time stamp must be specified
in
Generalized
Time as defined by RFC 4517. The format is effectively
yyyymmddHHMMSSZ
where the minutes and seconds are
optional. The ‘Z
’ suffix indicates
that the time stamp is in Coordinated Universal Time (UTC). It is also
possible to specify a timezone offset from UTC in hours and minutes instead
of a ‘Z
’. For example,
‘-0500
’ would correspond to Eastern
Standard time in the US. As an extension, if no
‘Z
’ or timezone offset is specified,
local time will be used.
The following are all valid time stamps:
20170214083000Z 2017021408Z 20160315220000-0500 20151201235900
A command may have a timeout associated with it. If the timeout
expires before the command has exited, the command will be terminated. The
timeout may be specified in combinations of days, hours, minutes and seconds
with a single-letter case-insensitive suffix that indicates the unit of
time. For example, a timeout of 7 days, 8 hours, 30 minutes and 10 seconds
would be written as 7d8h30m10s
. If a number is
specified without a unit, seconds are assumed. Any of the days, minutes,
hours or seconds may be omitted. The order must be from largest to smallest
unit and a unit may not be specified more than once.
The following are all
valid timeout
values: 7d8h30m10s
, 14d
,
8h30m
, 600s
,
3600
. The following are
invalid
timeout values: 12m2w1d
,
30s10m4h
, 1d2d3h
.
This option is only supported by version 1.8.20 or higher.
A command may have zero or more tags associated with it. The
following tag values are supported: EXEC
,
NOEXEC
, FOLLOW
,
NOFOLLOW
, LOG_INPUT
,
NOLOG_INPUT
, LOG_OUTPUT
,
NOLOG_OUTPUT
, MAIL
,
NOMAIL
, PASSWD
,
NOPASSWD
, SETENV
, and
NOSETENV
. Once a tag is set on a
Cmnd
, subsequent Cmnd
s in
the Cmnd_Spec_List
, inherit the tag unless it is
overridden by the opposite tag (in other words,
PASSWD
overrides NOPASSWD
and NOEXEC
overrides
EXEC
).
If sudo
has been compiled with
noexec support and the underlying operating system
supports it, the NOEXEC
tag can be used to
prevent a dynamically-linked executable from running further commands
itself.
In the following example, user aaron may run /usr/bin/more and /usr/bin/vi but shell escapes will be disabled.
aaron shanty = NOEXEC: /usr/bin/more, /usr/bin/vi
See the
Preventing shell
escapes section below for more details on how
NOEXEC
works and whether or not it will work on
your system.
sudoedit
will not
open a file that is a symbolic link unless the
sudoedit_follow option is enabled. The
FOLLOW and NOFOLLOW tags override the
value of sudoedit_follow and can be used to permit (or
deny) the editing of symbolic links on a per-command basis. These tags are
only effective for the sudoedit command and are ignored
for all other commands.These tags override the value of the log_input option on a per-command basis. For more information, see the description of log_input in the SUDOERS OPTIONS section below.
These tags override the value of the log_output option on a per-command basis. For more information, see the description of log_output in the SUDOERS OPTIONS section below.
These tags provide fine-grained control over whether mail will
be sent when a user runs a command by overriding the value of the
mail_all_cmnds option on a per-command basis. They
have no effect when sudo
is run with the
-l
or -v
options. A
NOMAIL tag will also override the
mail_always and mail_no_perms
options. For more information, see the descriptions of
mail_all_cmnds, mail_always, and
mail_no_perms in the
SUDOERS OPTIONS section
below.
By default, sudo
requires that a user
authenticate him or herself before running a command. This behavior can
be modified via the NOPASSWD
tag. Like a
Runas_Spec
, the NOPASSWD
tag sets a default for the commands that follow it in the
Cmnd_Spec_List
. Conversely, the
PASSWD
tag can be used to reverse things. For
example:
ray rushmore = NOPASSWD: /bin/kill, /bin/ls, /usr/bin/lprm
would allow the user ray to run /bin/kill, /bin/ls, and /usr/bin/lprm as root on the machine rushmore without authenticating himself. If we only want ray to be able to run /bin/kill without a password the entry would be:
ray rushmore = NOPASSWD: /bin/kill, PASSWD: /bin/ls, /usr/bin/lprm
Note, however, that the PASSWD
tag has
no effect on users who are in the group specified by the
exempt_group option.
By default, if the
NOPASSWD
tag is applied to any of the entries
for a user on the current host, he or she will be able to run
“sudo -l
” without a password.
Additionally, a user may only run “sudo
-v
” without a password if the
NOPASSWD
tag is present for all a user's entries
that pertain to the current host. This behavior may be overridden via
the verifypw
and
listpw
options.
These tags override the value of the
setenv
option on a per-command basis. Note that if
SETENV
has been set for a command, the user may
disable the env_reset option from the command line via
the -E
option. Additionally, environment
variables set on the command line are not subject to the restrictions
imposed by env_check, env_delete, or
env_keep. As such, only trusted users should be
allowed to set variables in this manner. If the command matched is
ALL, the SETENV
tag is implied
for that command; this default may be overridden by use of the
NOSETENV
tag.
sudo
allows shell-style
wildcards
(aka meta or glob characters) to be used in host names, path names and
command line arguments in the sudoers file. Wildcard
matching is done via the glob(3) and
fnmatch(3) functions as specified by IEEE
Std 1003.1 (“POSIX.1”).
*
?
[...]
[!...]
\x
*
’,
‘?
’,
‘[
’, and
‘]
’.Character classes may be used if your system's
glob(3) and fnmatch(3) functions support
them. However, because the ‘:
’
character has special meaning in sudoers, it must be
escaped. For example:
/bin/ls [[\:alpha\:]]*
Would match any file name beginning with a letter.
Note that a forward slash
(‘/
’) will not be
matched by wildcards used in the file name portion of the command. This is
to make a path like:
/usr/bin/*
match /usr/bin/who but not /usr/bin/X11/xterm.
When matching the command line arguments, however, a slash does get matched by wildcards since command line arguments may contain arbitrary strings and not just path names.
?
’ or
‘*
’ will match across word boundaries,
which may be unexpected. For example, while a sudoers entry like:
%operator ALL = /bin/cat /var/log/messages*
will allow command like:
$ sudo cat /var/log/messages.1
It will also allow:
$ sudo cat /var/log/messages /etc/shadow
which is probably not what was intended. In most cases it is better to do command line processing outside of the sudoers file in a scripting language.
The following exceptions apply to the above rules:
""
""
is the only
command line argument in the sudoers file entry it means
that command is not allowed to be run with any
arguments./
’) will not be matched by a
wildcard.It is possible to include other sudoers files
from within the sudoers file currently being parsed using
the #include
and #includedir
directives.
This can be used, for example, to keep a site-wide sudoers file in addition to a local, per-machine file. For the sake of this example the site-wide sudoers file will be /etc/sudoers and the per-machine one will be /etc/sudoers.local. To include /etc/sudoers.local from within /etc/sudoers we would use the following line in /etc/sudoers:
#include /etc/sudoers.local
When sudo
reaches this line it will
suspend processing of the current file
(/etc/sudoers) and switch to
/etc/sudoers.local. Upon reaching the end of
/etc/sudoers.local, the rest of
/etc/sudoers will be processed. Files that are
included may themselves include other files. A hard limit of 128 nested
include files is enforced to prevent include file loops.
If the path to the include file is not fully-qualified (does not
begin with a ‘/
’), it must be located
in the same directory as the sudoers file it was included from. For example,
if /etc/sudoers contains the line:
#include sudoers.local
the file that will be included is /etc/sudoers.local.
The file name may also include the %h
escape, signifying the short form of the host name. In other words, if the
machine's host name is “xerxes”, then
#include /etc/sudoers.%h
will cause sudo
to include the file
/etc/sudoers.xerxes.
The #includedir
directive can be used to
create a sudoers.d directory that the system package
manager can drop sudoers file rules into as part of
package installation. For example, given:
#includedir /etc/sudoers.d
sudo
will suspend processing of
the current file and read each file in
/etc/sudoers.d, skipping file names that end in
‘~
’ or contain a
‘.
’ character to avoid causing
problems with package manager or editor temporary/backup files. Files are
parsed in sorted lexical order. That is,
/etc/sudoers.d/01_first will be parsed before
/etc/sudoers.d/10_second. Be aware that because the
sorting is lexical, not numeric,
/etc/sudoers.d/1_whoops would be loaded
after
/etc/sudoers.d/10_second. Using a consistent number
of leading zeroes in the file names can be used to avoid such problems.
After parsing the files in the directory, control returns to the file that
contained the #includedir
directive.
Note that unlike files included via
#include
, visudo
will not
edit the files in a #includedir
directory unless one
of them contains a syntax error. It is still possible to run
visudo
with the -f
flag to
edit the files directly, but this will not catch the redefinition of an
alias that is also present in a different file.
The pound sign (‘#
’) is used
to indicate a comment (unless it is part of a #include directive or unless
it occurs in the context of a user name and is followed by one or more
digits, in which case it is treated as a uid). Both the comment character
and any text after it, up to the end of the line, are ignored.
The reserved word ALL is a built-in
alias that always causes a match to succeed. It can be
used wherever one might otherwise use a Cmnd_Alias
,
User_Alias
, Runas_Alias
, or
Host_Alias
. You should not try to define your own
alias called ALL as the built-in alias
will be used in preference to your own. Please note that using
ALL can be dangerous since in a command context, it allows
the user to run any command on the system.
An exclamation point (‘!
’)
can be used as a logical not operator in a list or
alias as well as in front of a
Cmnd
. This allows one to exclude certain values. For
the ‘!
’ operator to be effective,
there must be something for it to exclude. For example, to match all users
except for root one would use:
ALL,!root
If the ALL, is omitted, as in:
!root
it would explicitly deny root but not match any other users. This is different from a true “negation” operator.
Note, however, that using a
‘!
’ in conjunction with the built-in
ALL alias to allow a user to run “all but a
few” commands rarely works as intended (see
SECURITY NOTES below).
Long lines can be continued with a backslash
(‘\
’) as the last character on the
line.
White space between elements in a list as well as special
syntactic characters in a User Specification
(‘=
’,
‘:
’,
‘(
’,
‘)
’) is optional.
The following characters must be escaped with a backslash
(‘\
’) when used as part of a word
(e.g., a user name or host name): ‘!
’,
‘=
’,
‘:
’,
‘,
’,
‘(
’,
‘)
’,
‘\
’.
sudo
's behavior can be modified by
Default_Entry
lines, as explained earlier. A list of
all supported Defaults parameters, grouped by type, are listed below.
sudo
will set the
HOME
environment variable to the home directory of
the target user (which is root unless the -u
option is used). This effectively means that the
-H
option is always implied. Note that by default,
HOME
will be set to the home directory of the
target user when the env_reset option is enabled, so
always_set_home
only has an effect for configurations where either
env_reset is disabled or HOME
is
present in the env_keep list. This flag is
off by default.PASSWD
and
NOPASSWD
tags. This flag is on
by default.sudo
's
-C
option which overrides the default starting
point at which sudo
begins closing open file
descriptors. This flag is off by default.sudo
is configured to log a command's
input or output, the I/O logs will be compressed using
zlib. This flag is on by default when
sudo
is compiled with zlib
support.sudo
runs a command as the foreground
process as long as sudo
itself is running in the
foreground. When the
exec_background
flag is enabled and the command is being run in a pty (due to I/O logging
or the use_pty flag), the command will be run as a
background process. Attempts to read from the controlling terminal (or to
change terminal settings) will result in the command being suspended with
the SIGTTIN
signal (or
SIGTTOU
in the case of terminal settings). If this
happens when sudo
is a foreground process, the
command will be granted the controlling terminal and resumed in the
foreground with no user intervention required. The advantage of initially
running the command in the background is that sudo
need not read from the terminal unless the command explicitly requests it.
Otherwise, any terminal input must be passed to the command, whether it
has required it or not (the kernel buffers terminals so it is not possible
to tell whether the command really wants the input). This is different
from historic sudo behavior or when the command is not
being run in a pty.
For this to work seamlessly, the operating
system must support the automatic restarting of system calls.
Unfortunately, not all operating systems do this by default, and even
those that do may have bugs. For example, macOS fails to restart the
tcgetattr
()
and
tcsetattr
()
system calls (this is a bug in macOS). Furthermore, because this
behavior depends on the command stopping with the
SIGTTIN
or SIGTTOU
signals, programs that catch these signals and suspend themselves with a
different signal (usually SIGTOP
) will not be
automatically foregrounded. Some versions of the linux
su(1) command behave this way. This flag is
off by default.
This setting is only supported by version 1.8.7 or higher. It has no effect unless I/O logging is enabled or the use_pty flag is enabled.
visudo
will use the value of the
SUDO_EDITOR
, VISUAL
or
EDITOR
environment variables before falling back
on the default editor list. Note that this may create a security hole as
it allows the user to run any arbitrary command as root without logging. A
safer alternative is to place a colon-separated list of editors in the
editor variable. visudo
will
then only use SUDO_EDITOR
,
VISUAL
or EDITOR
if they
match a value specified in editor. If the
env_reset flag is enabled, the
SUDO_EDITOR
, VISUAL
and/or
EDITOR
environment variables must be present in
the env_keep list for the
env_editor
flag to function when visudo
is invoked via
sudo
. This flag is on by
default.sudo
will run the command in a minimal
environment containing the TERM
,
PATH
, HOME
,
MAIL
, SHELL
,
LOGNAME
, USER
and
SUDO_*
variables. Any variables in the caller's
environment or in the file specified by the
restricted_env_file option that match the
env_keep
and env_check
lists are then added, followed by any variables present in the file
specified by the env_file option (if any). The contents
of the env_keep
and
env_check
lists, as modified by global Defaults
parameters in sudoers, are displayed when
sudo
is run by root with the
-V
option. If the secure_path
option is set, its value will be used for the PATH
environment variable. This flag is on by default.sudo
uses the glob(3)
function to do shell-style globbing when matching path names. However,
since it accesses the file system, glob(3) can take a
long time to complete for some patterns, especially when the pattern
references a network file system that is mounted on demand (auto mounted).
The fast_glob option causes sudo
to use the fnmatch(3) function, which does not access
the file system to do its matching. The disadvantage of
fast_glob is that it is unable to match relative path
names such as ./ls or
../bin/ls. This has security implications when
path names that include globbing characters are used with the negation
operator, ‘!
’, as such rules can be
trivially bypassed. As such, this option should not be used when the
sudoers file contains rules that contain negated path
names which include globbing characters. This flag is
off by default.hostname
command) does not contain the domain
name. In other words, instead of myhost you would use myhost.mydomain.edu.
You may still use the short form if you wish (and even mix the two). This
option is only effective when the “canonical” host name, as
returned by the
getaddrinfo
()
or
gethostbyname
()
function, is a fully-qualified domain name. This is usually the case when
the system is configured to use DNS for host name resolution.
If the system is configured to use the
/etc/hosts file in preference to DNS, the
“canonical” host name may not be fully-qualified. The
order that sources are queried for host name resolution is usually
specified in the /etc/nsswitch.conf,
/etc/netsvc.conf,
/etc/host.conf, or, in some cases,
/etc/resolv.conf file. In the
/etc/hosts file, the first host name of the
entry is considered to be the “canonical” name; subsequent
names are aliases that are not used by sudoers
.
For example, the following hosts file line for the machine
“xyzzy” has the fully-qualified domain name as the
“canonical” host name, and the short version as an
alias.
192.168.1.1 xyzzy.sudo.ws
xyzzy
If the machine's hosts file entry is not formatted properly, the fqdn option will not be effective if it is queried before DNS.
Beware that when using DNS for host name resolution, turning
on fqdn requires sudoers
to
make DNS lookups which renders sudo
unusable if
DNS stops working (for example if the machine is disconnected from the
network). Also note that just like with the hosts file, you must use the
“canonical” name as DNS knows it. That is, you may not use
a host alias (CNAME
entry) due to performance
issues and the fact that there is no way to get all aliases from
DNS.
This flag is on by default.
sudoers
cannot
write to the audit log. If enabled, an audit log write failure is not
treated as a fatal error. If disabled, a command may only be run after the
audit event is successfully written. This flag is only effective on
systems for which sudoers
supports audit logging,
including FreeBSD, Linux, macOS and Solaris. This
flag is on by default.sudo
will ignore "." or
"" (both denoting current directory) in the
PATH
environment variable; the
PATH
itself is not modified. This flag is
off by default.sudoers
cannot
write to the I/O log. If enabled, an I/O log write failure is not treated
as a fatal error. If disabled, the command will be terminated if the I/O
log cannot be written to. This flag is off by
default.sudoers
cannot
write to the log file. If enabled, a log file write failure is not treated
as a fatal error. If disabled, a command may only be run after the log
file entry is successfully written. This flag only has an effect when
sudoers
is configured to use file-based logging
via the logfile option. This flag is
on by default.sudo
how to behave when no
specific LDAP entries have been matched, this sudoOption is only
meaningful for the cn=defaults
section. This flag
is off by default.sudo
will not produce a warning if it
encounters an unknown Defaults entry in the sudoers file
or an unknown sudoOption in LDAP. This flag is off by
default.sudo
will insult users when they enter an
incorrect password. This flag is off by default.sudo
log file. This flag is off
by default.sudo
will run the command in a pseudo-tty
and log all user input. If the standard input is not connected to the
user's tty, due to I/O redirection or because the command is part of a
pipeline, that input is also captured and stored in a separate log file.
Anything sent to the standard input will be consumed, regardless of
whether or not the command run via sudo
is
actually reading the standard input. This may have unexpected results when
using sudo
in a shell script that expects to
process the standard input. For more information about I/O logging, see
the I/O LOG FILES section. This
flag is off by default.sudo
will run the command in a pseudo-tty
and log all output that is sent to the screen, similar to the
script(1) command. For more information about I/O
logging, see the I/O LOG FILES
section. This flag is off by default.sudo
log file. This flag is off
by default.sudo
(this includes
sudoedit
). No mail will be sent if the user runs
sudo
with the -l
or
-v
option unless there is an authentication error
and the mail_badpass flag is also set. This flag is
off by default.sudo
. This flag is off by
default.sudo
does not enter the correct password. If the
command the user is attempting to run is not permitted by
sudoers
and one of the
mail_all_cmnds, mail_always,
mail_no_host,
mail_no_perms or
mail_no_user
flags are set, this flag will have no effect. This flag is
off by default.sudo
but the
command they are trying is not listed in their sudoers
file entry or is explicitly denied. This flag is off by
default.sudoers
will look up each group the
user is a member of by group ID to determine the group name (this is only
done once). The resulting list of the user's group names is used when
matching groups listed in the sudoers file. This works
well on systems where the number of groups listed in the
sudoers file is larger than the number of groups a
typical user belongs to. On systems where group lookups are slow, where
users may belong to a large number of groups, and where the number of
groups listed in the sudoers file is relatively small,
it may be prohibitively expensive and running commands via
sudo
may take longer than normal. On such systems
it may be faster to use the match_group_by_gid flag to
avoid resolving the user's group IDs to group names. In this case,
sudoers
must look up any group name listed in the
sudoers file and use the group ID instead of the group
name when determining whether the user is a member of the group.
Note that if match_group_by_gid is enabled,
group database lookups performed by sudoers
will
be keyed by group name as opposed to group ID. On systems where there
are multiple sources for the group database, it is possible to have
conflicting group names or group IDs in the local
/etc/group file and the remote group database.
On such systems, enabling or disabling
match_group_by_gid can be used to choose whether group
database queries are performed by name (enabled) or ID (disabled), which
may aid in working around group entry conflicts.
The match_group_by_gid flag has no effect when sudoers data is stored in LDAP. This flag is off by default.
This setting is only supported by version 1.8.18 or higher.
sudo
only matched the user name and domain for
netgroups used in a User_List
and only matched the
host name and domain for netgroups used in a
Host_List
. This flag is off by
default.sudo
will behave as
if the NOEXEC
tag has been set, unless overridden
by an EXEC
tag. See the description of
EXEC and NOEXEC above as well as the
Preventing shell
escapes section at the end of this manual. This flag is
off by default.sudo
will create a new PAM session for the command to be run in. Disabling
pam_session may be needed on older PAM implementations
or on operating systems where opening a PAM session changes the utmp or
wtmp files. If PAM session support is disabled, resource limits may not be
updated for the command being run. If pam_session,
pam_setcred, and use_pty are disabled
and I/O logging has not been configured, sudo
will
execute the command directly instead of running it as a child process.
This flag is on by default.
This setting is only supported by version 1.8.7 or higher.
sudo
will attempt to establish credentials for the target user by default, if
supported by the underlying authentication system. One example of a
credential is a Kerberos ticket. If pam_session,
pam_setcred, and use_pty are disabled
and I/O logging has not been configured, sudo
will
execute the command directly instead of running it as a child process.
This flag is on by default.
This setting is only supported by version 1.8.8 or higher.
SUDO_PROMPT
environment variable will always be
used and will replace the prompt provided by a PAM module or other
authentication method. This flag is off by default.sudo
will tell the user when a command
could not be found in their PATH
environment
variable. Some sites may wish to disable this as it could be used to
gather information on the location of executables that the normal user
does not have access to. The disadvantage is that if the executable is
simply not in the user's PATH
,
sudo
will tell the user that they are not allowed
to run it, which can be confusing. This flag is on by
default.sudo
will initialize the group vector
to the list of groups the target user is in. When
preserve_groups
is set, the user's existing group vector is left unaltered. The real and
effective group IDs, however, are still set to match the target user. This
flag is off by default.sudo
reads the password like most
other Unix programs, by turning off echo until the user hits the return
(or enter) key. Some users become confused by this as it appears to them
that sudo
has hung at this point. When
pwfeedback
is set, sudo
will provide visual feedback when the
user presses a key. Note that this does have a security impact as an
onlooker may be able to determine the length of the password being
entered. This flag is off by default.sudo
will only run when the user is logged
in to a real tty. When this flag is set, sudo
can
only be run from a login session and not via other means such as
cron(8) or cgi-bin scripts. This flag is
off by default.sudo
too. Disabling
this prevents users from “chaining”
sudo
commands to get a root shell by doing
something like “sudo sudo /bin/sh
”.
Note, however, that turning off root_sudo will also
prevent root from running sudoedit
. Disabling
root_sudo provides no real additional security; it
exists purely for historical reasons. This flag is on by
default.sudo
will prompt for the root password
instead of the password of the invoking user when running a command or
editing a file. This flag is off by default.sudo
will prompt for the password of the
user defined by the runas_default option (defaults to
root
) instead of the password of the invoking user
when running a command or editing a file. This flag is
off by default.sudo
is invoked with the
-s
option the HOME
environment variable will be set to the home directory of the target user
(which is root unless the -u
option is used). This
effectively makes the -s
option imply
-H
. Note that HOME
is
already set when the env_reset option is enabled, so
set_home is
only effective for configurations where either env_reset
is disabled or HOME
is present in the
env_keep list. This flag is off by
default.sudo
will set the
LOGNAME
and USER
environment variables to the name of the target user (usually root unless
the -u
option is given). However, since some
programs (including the RCS revision control system) use
LOGNAME
to determine the real identity of the
user, it may be desirable to change this behavior. This can be done by
negating the set_logname option. Note that
set_logname
will have no effect if the env_reset option has not been
disabled and the env_keep list contains
LOGNAME
or USER
. This flag
is on by default.sudo
will create an entry in the
utmp (or utmpx) file when a pseudo-tty is allocated. A pseudo-tty is
allocated by sudo
when the
log_input, log_output or
use_pty flags are enabled. By default, the new entry
will be a copy of the user's existing utmp entry (if any), with the tty,
time, type and pid fields updated. This flag is on by
default.-E
option. Additionally,
environment variables set via the command line are not subject to the
restrictions imposed by env_check,
env_delete, or env_keep. As such, only
trusted users should be allowed to set variables in this manner. This flag
is off by default.sudo
is invoked with no arguments it
acts as if the -s
option had been given. That is,
it runs a shell as root (the shell is determined by the
SHELL
environment variable if it is set, falling
back on the shell listed in the invoking user's /etc/passwd entry if not).
This flag is off by default.sudo
executes a command the real
and effective UIDs are set to the target user (root by default). This
option changes that behavior such that the real UID is left as the
invoking user's UID. In other words, this makes
sudo
act as a setuid wrapper. This can be useful
on systems that disable some potentially dangerous functionality when a
program is run setuid. This option is only effective on systems that
support either the setreuid(2) or
setresuid(2) system call. This flag is
off by default.sudoedit
will check all directory
components of the path to be edited for writability by the invoking user.
Symbolic links will not be followed in writable directories and
sudoedit
will refuse to edit a file located in a
writable directory. These restrictions are not enforced when
sudoedit
is run by root. On some systems, if all
directory components of the path to be edited are not readable by the
target user, sudoedit
will be unable to edit the
file. This flag is on by default.
This setting was first introduced in version 1.8.15 but initially suffered from a race condition. The check for symbolic links in writable intermediate directories was added in version 1.8.16.
sudoedit
will not follow symbolic
links when opening files. The sudoedit_follow option can
be enabled to allow sudoedit
to open symbolic
links. It may be overridden on a per-command basis by the
FOLLOW and NOFOLLOW tags. This flag is
off by default.
This setting is only supported by version 1.8.15 or higher.
This setting is only supported by version 1.8.21 or higher.
sudo
will prompt for the password of the
user specified by the -u
option (defaults to
root
) instead of the password of the invoking user
when running a command or editing a file. Note that this flag precludes
the use of a uid not listed in the passwd database as an argument to the
-u
option. This flag is off by
default.sudo
will use a separate record in the
time stamp file for each terminal. If disabled, a single record is used
for all login sessions.
This option has been superseded by the timestamp_type option.
sudo
will set the umask as specified in
the sudoers file without modification. This makes it
possible to specify a umask in the sudoers file that is
more permissive than the user's own umask and matches historical behavior.
If
umask_override
is not set, sudo
will set the umask to be the
union of the user's umask and what is specified in
sudoers. This flag is off by
default.+
’), may be used in place of a user
or host. For LDAP-based sudoers, netgroup support requires an expensive
sub-string match on the server unless the
NETGROUP_BASE
directive is present in the /etc/sudo-ldap.conf
file. If netgroups are not needed, this option can be disabled to reduce
the load on the LDAP server. This flag is on by
default.sudo
is running in a terminal, the
command will be run in a pseudo-pty (even if no I/O logging is being
done). If the sudo
process is not attached to a
terminal, use_pty has no effect.
A malicious program run under sudo
may
be capable of injecting commands into the user's terminal or running a
background process that retains access to the user's terminal device
even after the main program has finished executing. By running the
command in a separate pseudo-pty, this attack is no longer possible.
This flag is off by default.
Timeout_Spec
section for a description of the
timeout syntax. This flag is off by default.
This setting is only supported by version 1.8.20 or higher.
sudo
will store the name of the runas user
when updating the utmp (or utmpx) file. By default,
sudo
stores the name of the invoking user. This
flag is off by default.sudo
will refuse to run if the user
must enter a password but it is not possible to disable echo on the
terminal. If the
visiblepw
flag is set, sudo
will prompt for a password even
when it would be visible on the screen. This makes it possible to run
things like “ssh somehost sudo ls
”
since by default, ssh(1) does not allocate a tty when
running a command. This flag is off by default.Integers:
sudo
will close all
open file descriptors other than standard input, standard output and
standard error (ie: file descriptors 0-2). The
closefrom
option can be used to specify a different file descriptor at which to
start closing. The default is 3
.Timeout_Spec
section for a
description of the timeout syntax.
This setting is only supported by version 1.8.20 or higher.
%{seq}
” escape in the I/O log file
(see the iolog_dir description below for more
information). While the value substituted for
“%{seq}
” is in base 36,
maxseq itself should be expressed in decimal. Values
larger than 2176782336 (which corresponds to the base 36 sequence number
“ZZZZZZ”) will be silently truncated to 2176782336. The
default value is 2176782336.
Once the local sequence number reaches the value of
maxseq, it will “roll over” to zero,
after which sudoers
will truncate and re-use any
existing I/O log path names.
This setting is only supported by version 1.8.7 or higher.
sudo
logs the failure and exits. The default is
3
.sudoers
creates log messages up to 980
bytes which corresponds to the historic BSD syslog
implementation which used a 1024 byte buffer to store the message, date,
hostname and program name. To prevent syslog messages from being
truncated, sudoers
will split up log messages that
are larger than syslog_maxlen bytes. When a message is
split, additional parts will include the string “(command
continued)” after the user name and before the continued command
line arguments.
This setting is only supported by version 1.8.19 or higher.
Integers that can be used in a boolean context:
80
(use 0 or negate the option to disable word
wrap).sudo
password prompt
times out, or 0
for no timeout. The timeout may
include a fractional component if minute granularity is insufficient, for
example 2.5
. The default is
0
.sudo
will
ask for a passwd again. The timeout may include a fractional component if
minute granularity is insufficient, for example
2.5
. The default is 15
.
Set this to 0
to always prompt for a password. If
set to a value less than 0
the user's time stamp
will not expire until the system is rebooted. This can be used to allow
users to create or delete their own time stamps via
“sudo -v
” and
“sudo -k
” respectively.0022
. This guarantees that
sudo
never lowers the umask when running a
command. Note: on systems that use PAM, the default PAM configuration may
specify its own umask which will override the value set in
sudoers.Strings:
%d
’ escape which
will expand to the number of failed password attempts. If set, it
overrides the default message, %d incorrect password
attempt(s)
.Sorry, try again.
unless insults are
enabled.:
’) separated list of
editors path names used by sudoedit
and
visudo
. For sudoedit
, this
list is used to find an editor when none of the
SUDO_EDITOR
, VISUAL
or
EDITOR
environment variables are set to an editor
that exists and is executable. For visudo
, it is
used as a white list of allowed editors; visudo
will choose the editor that matches the user's
SUDO_EDITOR
, VISUAL
or
EDITOR
environment variable if possible, or the
first editor in the list that exists and is executable if not. Unless
invoked as sudoedit
, sudo
does not preserve the SUDO_EDITOR
,
VISUAL
and EDITOR
environment variables by default, even when the
env_reset option is enabled. The default is
/usr/bin/editor.LOG_INPUT
or LOG_OUTPUT
tags are present for a command. The session sequence number, if any, is
stored in the directory. The default is
/var/log/sudo-io.
The following percent
(‘%
’) escape sequences are
supported:
%{seq}
%{user}
%{group}
%{runas_user}
%{runas_group}
%{hostname}
%{command}
In addition, any escape sequences supported by the system's strftime(3) function will be expanded.
To include a literal ‘%
’
character, the string ‘%%
’ should
be used.
LOG_INPUT
or LOG_OUTPUT
tags are present for a command. Note that iolog_file may
contain directory components. The default is
“%{seq}
”.
See the iolog_dir option above for a list of
supported percent (‘%
’) escape
sequences.
In addition to the escape sequences, path names that end in
six or more X
s will have the
X
s replaced with a unique combination of digits
and letters, similar to the mktemp(3) function.
If the path created by concatenating
iolog_dir and iolog_file already
exists, the existing I/O log file will be truncated and overwritten
unless iolog_file ends in six or more
X
s.
sudo
will flush I/O log data to disk after
each write instead of buffering it. This makes it possible to view the
logs in real-time as the program is executing but may significantly reduce
the effectiveness of I/O log compression. This flag is
off by default.
This setting is only supported by version 1.8.20 or higher.
This setting is only supported by version 1.8.19 or higher.
This setting is only supported by version 1.8.19 or higher.
This setting can be useful when the I/O logs are stored on a
Network File System (NFS) share. Having a dedicated user own the I/O log
files means that sudoers
does not write to the
log files as user ID 0, which is usually not permitted by NFS.
This setting is only supported by version 1.8.19 or higher.
sudo
stores per-user
lecture status files. Once a user has received the lecture, a zero-length
file is created in this directory so that sudo
will not lecture the user again. This directory should
not be cleared when the system reboots. The default is
/var/lib/sudo/lectured.%h
will expand to the host name of the machine.
Default is “*** SECURITY information for %h
***
”.sudo
version 1.8.1 this option is no longer
supported. The path to the noexec file should now be set in the
sudo.conf(5) file.-i
option is specified. The default value
is “sudo
”. See the description of
pam_service
for more information.
This setting is only supported by version 1.8.8 or higher.
sudo
”.
This setting is only supported by version 1.8.8 or higher.
-p
option or the
SUDO_PROMPT
environment variable. The following
percent (‘%
’) escape sequences are
supported:
%H
%h
%p
%U
%u
%%
%
characters are collapsed
into a single %
characterOn systems that use PAM for authentication, passprompt will only be used if the prompt provided by the PAM module matches the string “Password: ” or “username's Password: ”. This ensures that the passprompt setting does not interfere with challenge-response style authentication. The passprompt_override flag can be used to change this behavior.
The default value is “[sudo] password
for %p:
”.
sudo
is built
with SELinux support.-u
option is not specified on the command line. This defaults to
root
.C
”.sudoers
uses per-user time stamp files for
credential caching. The timestamp_type option can be
used to specify the type of time stamp record used. It has the following
possible values:
sudo
is used multiple times in a pipeline, but
this does not affect authentication.15
by default). Commands run via
sudo
with a different parent process ID, for
example from a shell script, will be authenticated separately.15
by default).The default value is tty.
This setting is only supported by version 1.8.21 or higher.
sudo
stores its time stamp
files. This directory should be cleared when the system reboots. The
default is /run/sudo/ts.root
.sudo
is built
with SELinux support.Strings that can be used in a boolean context:
VARIABLE=value
” or
“export VARIABLE=value
”. The value
may optionally be surrounded by single or double quotes. Variables in this
file are only added if the variable does not already exist in the
environment. This file is considered to be part of the security policy,
its contents are not subject to other sudo
environment restrictions such as env_keep and
env_check.%
prefix. This is not set by default.sudo
will execute a command by
its path or by an open file descriptor. It has the following possible
values:
The default value is digest_only. This avoids a time of check versus time of use race condition when the command is located in a directory writable by the invoking user.
Note that fdexec will change the first
element of the argument vector for scripts ($0 in the shell) due to the
way the kernel runs script interpreters. Instead of being a normal path,
it will refer to a file descriptor. For example,
/dev/fd/4 on Solaris and
/proc/self/fd/4 on Linux. A workaround is to use
the SUDO_COMMAND
environment variable
instead.
The fdexec setting is only used when the command is matched by path name. It has no effect if the command is matched by the built-in ALL alias.
This setting is only supported by version 1.8.20 or higher. If the operating system does not support the fexecve(2) system call, this setting has no effect.
sudoers
group plugin with
optional arguments. The string should consist of the plugin path, either
fully-qualified or relative to the /usr/lib/sudo
directory, followed by any configuration arguments the plugin requires.
These arguments (if any) will be passed to the plugin's initialization
function. If arguments are present, the string must be enclosed in double
quotes ("").
For more information see GROUP PROVIDER PLUGINS.
sudo
.If no value is specified, a value of once is implied. Negating the option results in a value of never being used. The default value is once.
sudo
lecture that will be used in place of the standard lecture if the named
file exists. By default, sudo
uses a built-in
lecture.sudo
with the -l
option.
It has the following possible values:
NOPASSWD
flag set to avoid
entering a password.-l
option.NOPASSWD
flag
set to avoid entering a password.-l
option.If no value is specified, a value of any is implied. Negating the option results in a value of never being used. The default value is any.
sudo
log file (not the syslog log
file). Setting a path turns on logging to a file; negating this option
turns it off. By default, sudo
logs via
syslog.-t
.sudo
interpreting the @
sign. Defaults to the name of
the user running sudo
.sudo
interpreting the @
sign. Defaults to root
.VARIABLE=value
” or
“export VARIABLE=value
”. The value
may optionally be surrounded by single or double quotes. Variables in this
file are only added if the variable does not already exist in the
environment. Unlike env_file, the file's contents are
not trusted and are processed in a manner similar to that of the invoking
user's environment. If env_reset is enabled, variables
in the file will only be added if they are matched by either the
env_check or env_keep list. If
env_reset is disabled, variables in the file are added
as long as they are not matched by the env_delete list.
In either case, the contents of restricted_env_file are
processed before the contents of env_file.sudo
. If you
don't trust the people running sudo
to have a sane
PATH
environment variable you may want to use
this. Another use is if you want to have the “root path” be
separate from the “user path”. Users in the group specified
by the exempt_group option are not affected by
secure_path. This option is not set by default.authpriv
.
The following syslog facilities are supported: authpriv (if your OS supports it), auth, daemon, user, local0, local1, local2, local3, local4, local5, local6, and local7.
alert
.
The following syslog priorities are supported: alert, crit, debug, emerg, err, info, notice, warning, and none. Negating the option or setting it to a value of none will disable logging of unsuccessful commands.
notice
.
See syslog_badpri for the list of supported syslog priorities. Negating the option or setting it to a value of none will disable logging of successful commands.
sudo
with the -v
option.
It has the following possible values:
NOPASSWD
flag set to avoid
entering a password.-v
option.NOPASSWD
flag
set to avoid entering a password.-v
option.If no value is specified, a value of all is implied. Negating the option results in a value of never being used. The default value is all.
Lists that can be used in a boolean context:
TZ
, “safe” means that the variable's
value does not contain any ‘%
’ or
‘/
’ characters. This can be used to
guard against printf-style format vulnerabilities in poorly-written
programs. The TZ
variable is considered unsafe if
any of the following are true:
:
’), that does not match
the location of the zoneinfo directory.PATH_MAX
.The argument may be a double-quoted, space-separated list or a
single value without double-quotes. The list can be replaced, added to,
deleted from, or disabled by using the =
,
+=
, -=
, and
!
operators respectively. Regardless of whether
the env_reset
option is enabled or disabled,
variables specified by env_check
will be
preserved in the environment if they pass the aforementioned check. The
global list of environment variables to check is displayed when
sudo
is run by root with the
-V
option.
=
,
+=
, -=
, and
!
operators respectively. The global list of
environment variables to remove is displayed when
sudo
is run by root with the
-V
option. Note that many operating systems will
remove potentially dangerous variables from the environment of any setuid
process (such as sudo
).sudo
-spawned
processes will receive. The argument may be a double-quoted,
space-separated list or a single value without double-quotes. The list can
be replaced, added to, deleted from, or disabled by using the
=
, +=
,
-=
, and !
operators
respectively. The global list of variables to keep is displayed when
sudo
is run by root with the
-V
option.The sudoers
plugin supports its own plugin
interface to allow non-Unix group lookups which can query a group source
other than the standard Unix group database. This can be used to implement
support for the nonunix_group
syntax described
earlier.
Group provider plugins are specified via the group_plugin Defaults setting. The argument to group_plugin should consist of the plugin path, either fully-qualified or relative to the /usr/lib/sudo directory, followed by any configuration options the plugin requires. These options (if specified) will be passed to the plugin's initialization function. If options are present, the string must be enclosed in double quotes ("").
The following group provider plugins are installed by default:
Defaults group_plugin="group_file.so /etc/sudo-group"
getgrnam
()
and
getgrid
().
This plugin can be used in instances where the user belongs to groups not
present in the user's supplemental group vector. This plugin takes no
options:
Defaults group_plugin=system_group.so
The group provider plugin API is described in detail in sudo_plugin(5).
sudoers
can log events using either
syslog(3) or a simple log file. The log format is almost
identical in both cases.
Commands that sudo runs are logged using the following format (split into multiple lines for readability):
date hostname progname: username : TTY=ttyname ; PWD=cwd ; \ USER=runasuser ; GROUP=runasgroup ; TSID=logid ; \ ENV=env_vars COMMAND=command
Where the fields are as follows:
sudo
was run on. This field
is only present when logging via syslog(3).sudo
.sudo
was run on, or “unknown” if
there was no terminal present.sudo
was run
in.Messages are logged using the locale specified by
sudoers_locale, which defaults to the
“C
” locale.
If the user is not allowed to run the command, the reason for the denial will follow the user name. Possible reasons include:
sudo
's -n
option was
specified but a password was required.If an error occurs, sudoers
will log a
message and, in most cases, send a message to the administrator via email.
Possible errors include:
sudoers
encountered an error when parsing the
specified file. In some cases, the actual error may be one line above or
below the line number listed, depending on the type of error.sudo
from running,
but the sudoers file should be checked using
visudo
.sudoers
tries to open the
sudoers file using group permissions to avoid this
problem. Consider either changing the ownership of
/etc/sudoers or adding an argument like
“sudoers_uid=N” (where ‘N’ is the user ID that
owns the sudoers file) to the end of the
sudoers
Plugin
line in the
sudo.conf(5) file.sudoers
Plugin
line in the
sudo.conf(5) file.sudoers
Plugin
line in the sudo.conf(5)
file.sudoers
Plugin
line in the
sudo.conf(5) file.sudoers
was unable to read or create the user's
time stamp file. This can happen when timestampowner is
set to a user other than root and the mode on
/run/sudo is not searchable by group or other. The
default mode for /run/sudo is 0711.sudoers
was unable to write to the user's time
stamp file.sudoers
will ignore the time stamp directory until
the owner is corrected.sudoers
will ignore the time
stamp directory until the mode is corrected.By default, sudoers
logs messages via
syslog(3). The
date,
hostname, and progname fields are added
by the system's
syslog
()
function, not sudoers
itself. As such, they may vary
in format on different systems.
The maximum size of syslog messages varies from system to system. The syslog_maxlen setting can be used to change the maximum syslog message size from the default value of 980 bytes. For more information, see the description of syslog_maxlen.
If the logfile option is set,
sudoers
will log to a local file, such as
/var/log/sudo. When logging to a file,
sudoers
uses a format similar to
syslog(3), with a few important differences:
!
’), word wrap will be
disabled.When I/O logging is enabled, sudo
will run
the command in a pseudo-tty and log all user input and/or output, depending
on which options are enabled. I/O is logged to the directory specified by
the iolog_dir option
(/var/log/sudo-io by default) using a unique session
ID that is included in the sudo
log line, prefixed
with “TSID=
”. The
iolog_file option may be used to control the format of the
session ID.
Each I/O log is stored in a separate directory that contains the following files:
sudo
, the name of the target user, the
name of the target group (optional), the terminal that
sudo
was run from, the number of rows and columns
of the terminal, the working directory the command was run from and the
path name of the command itself (with arguments if present)All files other than log
are compressed in gzip format unless the
compress_io
flag has been disabled. Due to buffering, it is not normally possible to
display the I/O logs in real-time as the program is executing The I/O log
data will not be complete until the program run by
sudo
has exited or has been terminated by a signal.
The
iolog_flush
flag can be used to disable buffering, in which case I/O log data is written
to disk as soon as it is available. The output portion of an I/O log file
can be viewed with the sudoreplay(8) utility, which can
also be used to list or search the available logs.
Note that user input may contain sensitive information such as
passwords (even if they are not echoed to the screen), which will be stored
in the log file unencrypted. In most cases, logging the command output via
log_output or LOG_OUTPUT
is all
that is required.
Since each session's I/O logs are stored in a separate directory,
traditional log rotation utilities cannot be used to limit the number of I/O
logs. The simplest way to limit the number of I/O is by setting the
maxseq option to the maximum number of logs you wish to
store. Once the I/O log sequence number reaches maxseq, it
will be reset to zero and sudoers
will truncate and
re-use any existing I/O logs.
sudoers
security policysudoers
security policy-i
mode on AIX and Linux
systemsBelow are example sudoers file entries. Admittedly, some of these are a bit contrived. First, we allow a few environment variables to pass and then define our aliases:
# Run X applications through sudo; HOME is used to find the # .Xauthority file. Note that other programs use HOME to find # configuration files and this may lead to privilege escalation! Defaults env_keep += "DISPLAY HOME" # User alias specification User_Alias FULLTIMERS = millert, mikef, dowdy User_Alias PARTTIMERS = bostley, jwfox, crawl User_Alias WEBMASTERS = will, wendy, wim # Runas alias specification Runas_Alias OP = root, operator Runas_Alias DB = oracle, sybase Runas_Alias ADMINGRP = adm, oper # Host alias specification Host_Alias SPARC = bigtime, eclipse, moet, anchor :\ SGI = grolsch, dandelion, black :\ ALPHA = widget, thalamus, foobar :\ HPPA = boa, nag, python Host_Alias CUNETS = 128.138.0.0/255.255.0.0 Host_Alias CSNETS = 128.138.243.0, 128.138.204.0/24, 128.138.242.0 Host_Alias SERVERS = master, mail, www, ns Host_Alias CDROM = orion, perseus, hercules # Cmnd alias specification Cmnd_Alias DUMPS = /usr/bin/mt, /usr/sbin/dump, /usr/sbin/rdump,\ /usr/sbin/restore, /usr/sbin/rrestore,\ sha224:0GomF8mNN3wlDt1HD9XldjJ3SNgpFdbjO1+NsQ== \ /home/operator/bin/start_backups Cmnd_Alias KILL = /usr/bin/kill Cmnd_Alias PRINTING = /usr/sbin/lpc, /usr/bin/lprm Cmnd_Alias SHUTDOWN = /usr/sbin/shutdown Cmnd_Alias HALT = /usr/sbin/halt Cmnd_Alias REBOOT = /usr/sbin/reboot Cmnd_Alias SHELLS = /usr/bin/sh, /usr/bin/csh, /usr/bin/ksh,\ /usr/local/bin/tcsh, /usr/bin/rsh,\ /usr/local/bin/zsh Cmnd_Alias SU = /usr/bin/su Cmnd_Alias PAGERS = /usr/bin/more, /usr/bin/pg, /usr/bin/less
Here we override some of the compiled in default values. We want
sudo
to log via syslog(3) using
the auth facility in all cases. We don't want to subject
the full time staff to the sudo
lecture, user
millert need not give a password, and we don't want to
reset the LOGNAME
or USER
environment variables when running commands as root. Additionally, on the
machines in the SERVERS
Host_Alias
, we keep an additional local log file and
make sure we log the year in each log line since the log entries will be
kept around for several years. Lastly, we disable shell escapes for the
commands in the PAGERS Cmnd_Alias
(/usr/bin/more, /usr/bin/pg
and /usr/bin/less). Note that this will not
effectively constrain users with sudo
ALL privileges.
# Override built-in defaults Defaults syslog=auth Defaults>root !set_logname Defaults:FULLTIMERS !lecture Defaults:millert !authenticate Defaults@SERVERS log_year, logfile=/var/log/sudo.log Defaults!PAGERS noexec
The User specification is the part that actually determines who may run what.
root ALL = (ALL) ALL %wheel ALL = (ALL) ALL
We let root and any user in group wheel run any command on any host as any user.
FULLTIMERS ALL = NOPASSWD: ALL
Full time sysadmins (millert, mikef, and dowdy) may run any command on any host without authenticating themselves.
PARTTIMERS ALL = ALL
Part time sysadmins
bostley,
jwfox,
and
crawl)
may run any command on any host but they must authenticate themselves first
(since the entry lacks the NOPASSWD
tag).
jack CSNETS = ALL
The user
jack may run any
command on the machines in the CSNETS alias (the networks
128.138.243.0
,
128.138.204.0
, and
128.138.242.0
). Of those networks, only
128.138.204.0
has an explicit netmask (in CIDR
notation) indicating it is a class C network. For the other networks in
CSNETS, the local machine's netmask will be used during
matching.
lisa CUNETS = ALL
The user
lisa may run any
command on any host in the
CUNETS
alias (the class B network 128.138.0.0
).
operator ALL = DUMPS, KILL, SHUTDOWN, HALT, REBOOT, PRINTING,\ sudoedit /etc/printcap, /usr/oper/bin/
The operator user may run commands limited to
simple maintenance. Here, those are commands related to backups, killing
processes, the printing system, shutting down the system, and any commands
in the directory /usr/oper/bin/. Note that one
command in the DUMPS
Cmnd_Alias includes a sha224
digest, /home/operator/bin/start_backups. This is
because the directory containing the script is writable by the operator
user. If the script is modified (resulting in a digest mismatch) it will no
longer be possible to run it via sudo
.
joe ALL = /usr/bin/su operator
The user joe may only su(1) to operator.
pete HPPA = /usr/bin/passwd [A-Za-z]*, !/usr/bin/passwd *root* %opers ALL = (: ADMINGRP) /usr/sbin/
Users in the
opers group may run
commands in /usr/sbin/ as themselves with any group
in the
ADMINGRP
Runas_Alias
(the
adm and
oper
groups).
The user
pete is allowed to
change anyone's password except for root on the
HPPA
machines. Because command line arguments are matched as a single,
concatenated string, the ‘*
’ wildcard
will match
multiple
words. This example assumes that passwd(1) does not take
multiple user names on the command line. Note that on GNU systems, options
to passwd(1) may be specified after the user argument. As
a result, this rule will also allow:
passwd username --expire
which may not be desirable.
bob SPARC = (OP) ALL : SGI = (OP) ALL
The user
bob may run anything
on the
SPARC
and SGI
machines as any user listed in the
OP
Runas_Alias
(root and
operator.)
jim +biglab = ALL
The user
jim may run any
command on machines in the
biglab
netgroup. sudo
knows that “biglab” is
a netgroup due to the ‘+
’ prefix.
+secretaries ALL = PRINTING, /usr/bin/adduser, /usr/bin/rmuser
Users in the secretaries netgroup need to help manage the printers as well as add and remove users, so they are allowed to run those commands on all machines.
fred ALL = (DB) NOPASSWD: ALL
The user
fred can run
commands as any user in the
DB
Runas_Alias
(oracle
or
sybase)
without giving a password.
john ALPHA = /usr/bin/su [!-]*, !/usr/bin/su *root*
On the ALPHA machines, user john may su to anyone except root but he is not allowed to specify any options to the su(1) command.
jen ALL, !SERVERS = ALL
The user
jen may run any
command on any machine except for those in the SERVERS
Host_Alias
(master, mail, www and ns).
jill SERVERS = /usr/bin/, !SU, !SHELLS
For any machine in the SERVERS
Host_Alias
,
jill may run any
commands in the directory /usr/bin/ except for those
commands belonging to the SU and SHELLS
Cmnd_Aliases
. While not specifically mentioned in
the rule, the commands in the
PAGERS
Cmnd_Alias
all reside in
/usr/bin and have the noexec
option set.
steve CSNETS = (operator) /usr/local/op_commands/
The user steve may run any command in the directory /usr/local/op_commands/ but only as user operator.
matt valkyrie = KILL
On his personal workstation, valkyrie, matt needs to be able to kill hung processes.
WEBMASTERS www = (www) ALL, (root) /usr/bin/su www
On the host www, any user in the
WEBMASTERS
User_Alias
(will, wendy, and wim), may run any
command as user www (which owns the web pages) or simply
su(1) to www.
ALL CDROM = NOPASSWD: /sbin/umount /CDROM,\ /sbin/mount -o nosuid\,nodev /dev/cd0a /CDROM
Any user may mount or unmount a CD-ROM on the machines in the
CDROM Host_Alias
(orion, perseus, hercules) without
entering a password. This is a bit tedious for users to type, so it is a
prime candidate for encapsulating in a shell script.
It is generally not effective to “subtract” commands
from ALL using the
‘!
’ operator. A user can trivially
circumvent this by copying the desired command to a different name and then
executing that. For example:
bill ALL = ALL, !SU, !SHELLS
Doesn't really prevent bill from running the commands listed in SU or SHELLS since he can simply copy those commands to a different name, or use a shell escape from an editor or other program. Therefore, these kind of restrictions should be considered advisory at best (and reinforced by policy).
In general, if a user has sudo ALL there is
nothing to prevent them from creating their own program that gives them a
root shell (or making their own copy of a shell) regardless of any
‘!
’ elements in the user
specification.
If the fast_glob option is in use, it is not possible to reliably negate commands where the path name includes globbing (aka wildcard) characters. This is because the C library's fnmatch(3) function cannot resolve relative paths. While this is typically only an inconvenience for rules that grant privileges, it can result in a security issue for rules that subtract or revoke privileges.
For example, given the following sudoers file entry:
john ALL = /usr/bin/passwd [a-zA-Z0-9]*, /usr/bin/chsh [a-zA-Z0-9]*,\ /usr/bin/chfn [a-zA-Z0-9]*, !/usr/bin/* root
User john can still run
/usr/bin/passwd root
if fast_glob
is enabled by changing to /usr/bin and running
./passwd root
instead.
Once sudo
executes a program, that program
is free to do whatever it pleases, including run other programs. This can be
a security issue since it is not uncommon for a program to allow shell
escapes, which lets a user bypass sudo
's access
control and logging. Common programs that permit shell escapes include
shells (obviously), editors, paginators, mail and terminal programs.
There are two basic approaches to this problem:
sudoedit
is a better solution to
running editors via sudo
. Due to the large number
of programs that offer shell escapes, restricting users to the set of
programs that do not is often unworkable.LD_PRELOAD
) to an alternate shared library. On
such systems, sudo
's noexec
functionality can be used to prevent a program run by
sudo
from executing any other programs. Note,
however, that this applies only to native dynamically-linked executables.
Statically-linked executables and foreign executables running under binary
emulation are not affected.
The noexec feature is known to work on
SunOS, Solaris, *BSD, Linux, IRIX, Tru64 UNIX, macOS, HP-UX 11.x and AIX
5.3 and above. It should be supported on most operating systems that
support the LD_PRELOAD
environment variable.
Check your operating system's manual pages for the dynamic linker
(usually ld.so, ld.so.1, dyld, dld.sl, rld, or loader) to see if
LD_PRELOAD
is supported.
On Solaris 10 and higher, noexec uses
Solaris privileges instead of the LD_PRELOAD
environment variable.
To enable noexec for a command, use the
NOEXEC
tag as documented in the User
Specification section above. Here is that example again:
aaron shanty = NOEXEC: /usr/bin/more, /usr/bin/vi
This allows user aaron to run /usr/bin/more and /usr/bin/vi with noexec enabled. This will prevent those two commands from executing other commands (such as a shell). If you are unsure whether or not your system is capable of supporting noexec you can always just try it out and check whether shell escapes work when noexec is enabled.
Note that restricting shell escapes is not a panacea. Programs
running as root are still capable of many potentially hazardous operations
(such as changing or overwriting files) that could lead to unintended
privilege escalation. In the specific case of an editor, a safer approach is
to give the user permission to run sudoedit
(see
below).
The sudoers
plugin includes
sudoedit
support which allows users to securely edit
files with the editor of their choice. As sudoedit
is a built-in command, it must be specified in the sudoers
file without a leading path. However, it may take command line arguments
just as a normal command does. Wildcards used in sudoedit
command line arguments are expected to be path names, so a forward slash
(‘/
’) will not be matched by a
wildcard.
Unlike other sudo
commands, the editor is
run with the permissions of the invoking user and with the environment
unmodified. More information may be found in the description of the
-e
option in sudo(8).
For example, to allow user operator to edit the “message of the day” file:
operator sudoedit /etc/motd
The operator user then runs sudoedit
as
follows:
$ sudoedit /etc/motd
The editor will run as the operator user, not root, on a temporary copy of /etc/motd. After the file has been edited, /etc/motd will be updated with the contents of the temporary copy.
Users should never be
granted sudoedit
permission to edit a file that
resides in a directory the user has write access to, either directly or via
a wildcard. If the user has write access to the directory it is possible to
replace the legitimate file with a link to another file, allowing the
editing of arbitrary files. To prevent this, starting with version 1.8.16,
symbolic links will not be followed in writable directories and
sudoedit
will refuse to edit a file located in a
writable directory unless the
sudoedit_checkdir
option has been disabled or the invoking user is root. Additionally, in
version 1.8.15 and higher, sudoedit
will refuse to
open a symbolic link unless either the sudoedit_follow
option is enabled or the sudoedit command is prefixed with
the FOLLOW
tag in the sudoers
file.
sudoers
will check the ownership of its
time stamp directory (/run/sudo/ts by default) and
ignore the directory's contents if it is not owned by root or if it is
writable by a user other than root. Older versions of
sudo
stored time stamp files in
/tmp; this is no longer recommended as it may be
possible for a user to create the time stamp themselves on systems that
allow unprivileged users to change the ownership of files they create.
While the time stamp directory
should be cleared
at reboot time, not all systems contain a /run or
/var/run directory. To avoid potential problems,
sudoers
will ignore time stamp files that date from
before the machine booted on systems where the boot time is available.
Some systems with graphical desktop environments allow
unprivileged users to change the system clock. Since
sudoers
relies on the system clock for time stamp
validation, it may be possible on such systems for a user to run
sudo
for longer than
timestamp_timeout by setting the clock back. To combat
this, sudoers
uses a monotonic clock (which never
moves backwards) for its time stamps if the system supports it.
sudoers
will not honor time stamps set far
in the future. Time stamps with a date greater than current_time + 2 *
TIMEOUT
will be ignored and
sudoers
will log and complain.
If the timestamp_type option is set to “tty”, the time stamp record includes the device number of the terminal the user authenticated with. This provides per-terminal granularity but time stamp records may still outlive the user's session.
Unless the timestamp_type option is set to “global”, the time stamp record also includes the session ID of the process that last authenticated. This prevents processes in different terminal sessions from using the same time stamp record. On systems where a process's start time can be queried, the start time of the session leader is recorded in the time stamp record. If no terminal is present or the timestamp_type option is set to “ppid”, the start time of the parent process is used instead. In most cases this will prevent a time stamp record from being re-used without the user entering a password when logging out and back in again.
Versions 1.8.4 and higher of the sudoers
plugin support a flexible debugging framework that can help track down what
the plugin is doing internally if there is a problem. This can be configured
in the sudo.conf(5) file.
The sudoers
plugin uses the
same debug flag format as the sudo
front-end:
subsystem@priority.
The priorities used by sudoers
,
in order of decreasing severity, are: crit,
err,
warn,
notice,
diag,
info,
trace
and debug. Each priority, when specified, also includes
all priorities higher than it. For example, a priority of
notice would include debug messages logged at
notice and higher.
The following subsystems are used by the
sudoers
plugin:
User_Alias
,
Runas_Alias
, Host_Alias
and Cmnd_Alias
processingsudoers
Debug sudo /var/log/sudo_debug match@info,nss@info
For more information, see the sudo.conf(5) manual.
ssh(1), su(1), fnmatch(3), glob(3), mktemp(3), strftime(3), sudo.conf(5), sudo_plugin(5), sudoers.ldap(5), sudoers_timestamp(5), sudo(8), visudo(8)
Many people have worked on sudo
over the
years; this version consists of code written primarily by:
See the CONTRIBUTORS file in the sudo
distribution (https://www.sudo.ws/contributors.html) for an exhaustive list
of people who have contributed to sudo
.
The sudoers file should
always
be edited by the visudo
command which locks the file
and does grammatical checking. It is imperative that the
sudoers file be free of syntax errors since
sudo
will not run with a syntactically incorrect
sudoers file.
When using netgroups of machines (as opposed to users), if you
store fully qualified host name in the netgroup (as is usually the case),
you either need to have the machine's host name be fully qualified as
returned by the hostname
command or use the
fqdn option in sudoers.
If you feel you have found a bug in sudo
,
please submit a bug report at https://bugzilla.sudo.ws/
Limited free support is available via the sudo-users mailing list, see https://www.sudo.ws/mailman/listinfo/sudo-users to subscribe or search the archives.
sudo
is provided “AS IS” and
any express or implied warranties, including, but not limited to, the
implied warranties of merchantability and fitness for a particular purpose
are disclaimed. See the LICENSE file distributed with
sudo
or https://www.sudo.ws/license.html for
complete details.
December 20, 2018 | Sudo 1.8.27 |