glibc/manual/users.texi

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@node Users and Groups, System Information, Name Service Switch, Top
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@chapter Users and Groups
Every user who can log in on the system is identified by a unique number
called the @dfn{user ID}. Each process has an effective user ID which
says which user's access permissions it has.
Users are classified into @dfn{groups} for access control purposes. Each
process has one or more @dfn{group ID values} which say which groups the
process can use for access to files.
The effective user and group IDs of a process collectively form its
@dfn{persona}. This determines which files the process can access.
Normally, a process inherits its persona from the parent process, but
under special circumstances a process can change its persona and thus
change its access permissions.
Each file in the system also has a user ID and a group ID. Access
control works by comparing the user and group IDs of the file with those
of the running process.
The system keeps a database of all the registered users, and another
database of all the defined groups. There are library functions you
can use to examine these databases.
@menu
* User and Group IDs:: Each user has a unique numeric ID;
likewise for groups.
* Process Persona:: The user IDs and group IDs of a process.
* Why Change Persona:: Why a program might need to change
its user and/or group IDs.
* How Change Persona:: Changing the user and group IDs.
* Reading Persona:: How to examine the user and group IDs.
* Setting User ID:: Functions for setting the user ID.
* Setting Groups:: Functions for setting the group IDs.
* Enable/Disable Setuid:: Turning setuid access on and off.
* Setuid Program Example:: The pertinent parts of one sample program.
* Tips for Setuid:: How to avoid granting unlimited access.
* Who Logged In:: Getting the name of the user who logged in,
or of the real user ID of the current process.
* User Database:: Functions and data structures for
accessing the user database.
* Group Database:: Functions and data structures for
accessing the group database.
* Database Example:: Example program showing use of database
inquiry functions.
@end menu
@node User and Group IDs
@section User and Group IDs
@cindex login name
@cindex user name
@cindex user ID
Each user account on a computer system is identified by a @dfn{user
name} (or @dfn{login name}) and @dfn{user ID}. Normally, each user name
has a unique user ID, but it is possible for several login names to have
the same user ID. The user names and corresponding user IDs are stored
in a data base which you can access as described in @ref{User Database}.
@cindex group name
@cindex group ID
Users are classified in @dfn{groups}. Each user name also belongs to
one or more groups, and has one @dfn{default group}. Users who are
members of the same group can share resources (such as files) that are
not accessible to users who are not a member of that group. Each group
has a @dfn{group name} and @dfn{group ID}. @xref{Group Database},
for how to find information about a group ID or group name.
@node Process Persona
@section The Persona of a Process
@cindex persona
@cindex effective user ID
@cindex effective group ID
@c !!! bogus; not single ID. set of effective group IDs (and, in GNU,
@c set of effective UIDs) determines privilege. lying here and then
@c telling the truth below is confusing.
At any time, each process has a single user ID and a group ID which
determine the privileges of the process. These are collectively called
the @dfn{persona} of the process, because they determine ``who it is''
for purposes of access control. These IDs are also called the
@dfn{effective user ID} and @dfn{effective group ID} of the process.
Your login shell starts out with a persona which consists of your user
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ID and your default group ID.
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@c !!! also supplementary group IDs.
In normal circumstances, all your other processes inherit these values.
@cindex real user ID
@cindex real group ID
A process also has a @dfn{real user ID} which identifies the user who
created the process, and a @dfn{real group ID} which identifies that
user's default group. These values do not play a role in access
control, so we do not consider them part of the persona. But they are
also important.
Both the real and effective user ID can be changed during the lifetime
of a process. @xref{Why Change Persona}.
@cindex supplementary group IDs
In addition, a user can belong to multiple groups, so the persona
includes @dfn{supplementary group IDs} that also contribute to access
permission.
For details on how a process's effective user IDs and group IDs affect
its permission to access files, see @ref{Access Permission}.
The user ID of a process also controls permissions for sending signals
using the @code{kill} function. @xref{Signaling Another Process}.
@node Why Change Persona
@section Why Change the Persona of a Process?
The most obvious situation where it is necessary for a process to change
its user and/or group IDs is the @code{login} program. When
@code{login} starts running, its user ID is @code{root}. Its job is to
start a shell whose user and group IDs are those of the user who is
logging in. (To accomplish this fully, @code{login} must set the real
user and group IDs as well as its persona. But this is a special case.)
The more common case of changing persona is when an ordinary user
program needs access to a resource that wouldn't ordinarily be
accessible to the user actually running it.
For example, you may have a file that is controlled by your program but
that shouldn't be read or modified directly by other users, either
because it implements some kind of locking protocol, or because you want
to preserve the integrity or privacy of the information it contains.
This kind of restricted access can be implemented by having the program
change its effective user or group ID to match that of the resource.
Thus, imagine a game program that saves scores in a file. The game
program itself needs to be able to update this file no matter who is
running it, but if users can write the file without going through the
game, they can give themselves any scores they like. Some people
consider this undesirable, or even reprehensible. It can be prevented
by creating a new user ID and login name (say, @code{games}) to own the
scores file, and make the file writable only by this user. Then, when
the game program wants to update this file, it can change its effective
user ID to be that for @code{games}. In effect, the program must
adopt the persona of @code{games} so it can write the scores file.
@node How Change Persona
@section How an Application Can Change Persona
@cindex @code{setuid} programs
The ability to change the persona of a process can be a source of
unintentional privacy violations, or even intentional abuse. Because of
the potential for problems, changing persona is restricted to special
circumstances.
You can't arbitrarily set your user ID or group ID to anything you want;
only privileged processes can do that. Instead, the normal way for a
program to change its persona is that it has been set up in advance to
change to a particular user or group. This is the function of the setuid
and setgid bits of a file's access mode. @xref{Permission Bits}.
When the setuid bit of an executable file is set, executing that file
automatically changes the effective user ID to the user that owns the
file. Likewise, executing a file whose setgid bit is set changes the
effective group ID to the group of the file. @xref{Executing a File}.
Creating a file that changes to a particular user or group ID thus
requires full access to that user or group ID.
@xref{File Attributes}, for a more general discussion of file modes and
accessibility.
A process can always change its effective user (or group) ID back to its
real ID. Programs do this so as to turn off their special privileges
when they are not needed, which makes for more robustness.
@c !!! talk about _POSIX_SAVED_IDS
@node Reading Persona
@section Reading the Persona of a Process
Here are detailed descriptions of the functions for reading the user and
group IDs of a process, both real and effective. To use these
facilities, you must include the header files @file{sys/types.h} and
@file{unistd.h}.
@pindex unistd.h
@pindex sys/types.h
@comment sys/types.h
@comment POSIX.1
@deftp {Data Type} uid_t
This is an integer data type used to represent user IDs. In the GNU
library, this is an alias for @code{unsigned int}.
@end deftp
@comment sys/types.h
@comment POSIX.1
@deftp {Data Type} gid_t
This is an integer data type used to represent group IDs. In the GNU
library, this is an alias for @code{unsigned int}.
@end deftp
@comment unistd.h
@comment POSIX.1
@deftypefun uid_t getuid (void)
The @code{getuid} function returns the real user ID of the process.
@end deftypefun
@comment unistd.h
@comment POSIX.1
@deftypefun gid_t getgid (void)
The @code{getgid} function returns the real group ID of the process.
@end deftypefun
@comment unistd.h
@comment POSIX.1
@deftypefun uid_t geteuid (void)
The @code{geteuid} function returns the effective user ID of the process.
@end deftypefun
@comment unistd.h
@comment POSIX.1
@deftypefun gid_t getegid (void)
The @code{getegid} function returns the effective group ID of the process.
@end deftypefun
@comment unistd.h
@comment POSIX.1
@deftypefun int getgroups (int @var{count}, gid_t *@var{groups})
The @code{getgroups} function is used to inquire about the supplementary
group IDs of the process. Up to @var{count} of these group IDs are
stored in the array @var{groups}; the return value from the function is
the number of group IDs actually stored. If @var{count} is smaller than
the total number of supplementary group IDs, then @code{getgroups}
returns a value of @code{-1} and @code{errno} is set to @code{EINVAL}.
If @var{count} is zero, then @code{getgroups} just returns the total
number of supplementary group IDs. On systems that do not support
supplementary groups, this will always be zero.
Here's how to use @code{getgroups} to read all the supplementary group
IDs:
@smallexample
@group
gid_t *
read_all_groups (void)
@{
int ngroups = getgroups (0, NULL);
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gid_t *groups
= (gid_t *) xmalloc (ngroups * sizeof (gid_t));
int val = getgroups (ngroups, groups);
if (val < 0)
@{
free (groups);
return NULL;
@}
return groups;
@}
@end group
@end smallexample
@end deftypefun
@node Setting User ID
@section Setting the User ID
This section describes the functions for altering the user ID (real
and/or effective) of a process. To use these facilities, you must
include the header files @file{sys/types.h} and @file{unistd.h}.
@pindex unistd.h
@pindex sys/types.h
@comment unistd.h
@comment POSIX.1
@deftypefun int setuid (uid_t @var{newuid})
This function sets both the real and effective user ID of the process
to @var{newuid}, provided that the process has appropriate privileges.
@c !!! also sets saved-id
If the process is not privileged, then @var{newuid} must either be equal
to the real user ID or the saved user ID (if the system supports the
@code{_POSIX_SAVED_IDS} feature). In this case, @code{setuid} sets only
the effective user ID and not the real user ID.
@c !!! xref to discussion of _POSIX_SAVED_IDS
The @code{setuid} function returns a value of @code{0} to indicate
successful completion, and a value of @code{-1} to indicate an error.
The following @code{errno} error conditions are defined for this
function:
@table @code
@item EINVAL
The value of the @var{newuid} argument is invalid.
@item EPERM
The process does not have the appropriate privileges; you do not
have permission to change to the specified ID.
@end table
@end deftypefun
@comment unistd.h
@comment BSD
@deftypefun int setreuid (uid_t @var{ruid}, uid_t @var{euid})
This function sets the real user ID of the process to @var{ruid} and the
effective user ID to @var{euid}. If @var{ruid} is @code{-1}, it means
not to change the real user ID; likewise if @var{euid} is @code{-1}, it
means not to change the effective user ID.
The @code{setreuid} function exists for compatibility with 4.3 BSD Unix,
which does not support saved IDs. You can use this function to swap the
effective and real user IDs of the process. (Privileged processes are
not limited to this particular usage.) If saved IDs are supported, you
should use that feature instead of this function. @xref{Enable/Disable
Setuid}.
The return value is @code{0} on success and @code{-1} on failure.
The following @code{errno} error conditions are defined for this
function:
@table @code
@item EPERM
The process does not have the appropriate privileges; you do not
have permission to change to the specified ID.
@end table
@end deftypefun
@node Setting Groups
@section Setting the Group IDs
This section describes the functions for altering the group IDs (real
and effective) of a process. To use these facilities, you must include
the header files @file{sys/types.h} and @file{unistd.h}.
@pindex unistd.h
@pindex sys/types.h
@comment unistd.h
@comment POSIX.1
@deftypefun int setgid (gid_t @var{newgid})
This function sets both the real and effective group ID of the process
to @var{newgid}, provided that the process has appropriate privileges.
@c !!! also sets saved-id
If the process is not privileged, then @var{newgid} must either be equal
to the real group ID or the saved group ID. In this case, @code{setgid}
sets only the effective group ID and not the real group ID.
The return values and error conditions for @code{setgid} are the same
as those for @code{setuid}.
@end deftypefun
@comment unistd.h
@comment BSD
@deftypefun int setregid (gid_t @var{rgid}, fid_t @var{egid})
This function sets the real group ID of the process to @var{rgid} and
the effective group ID to @var{egid}. If @var{rgid} is @code{-1}, it
means not to change the real group ID; likewise if @var{egid} is
@code{-1}, it means not to change the effective group ID.
The @code{setregid} function is provided for compatibility with 4.3 BSD
Unix, which does not support saved IDs. You can use this function to
swap the effective and real group IDs of the process. (Privileged
processes are not limited to this usage.) If saved IDs are supported,
you should use that feature instead of using this function.
@xref{Enable/Disable Setuid}.
The return values and error conditions for @code{setregid} are the same
as those for @code{setreuid}.
@end deftypefun
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The GNU system also lets privileged processes change their supplementary
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group IDs. To use @code{setgroups} or @code{initgroups}, your programs
should include the header file @file{grp.h}.
@pindex grp.h
@comment grp.h
@comment BSD
@deftypefun int setgroups (size_t @var{count}, gid_t *@var{groups})
This function sets the process's supplementary group IDs. It can only
be called from privileged processes. The @var{count} argument specifies
the number of group IDs in the array @var{groups}.
This function returns @code{0} if successful and @code{-1} on error.
The following @code{errno} error conditions are defined for this
function:
@table @code
@item EPERM
The calling process is not privileged.
@end table
@end deftypefun
@comment grp.h
@comment BSD
@deftypefun int initgroups (const char *@var{user}, gid_t @var{gid})
The @code{initgroups} function effectively calls @code{setgroups} to
set the process's supplementary group IDs to be the normal default for
the user name @var{user}. The group ID @var{gid} is also included.
@c !!! explain that this works by reading the group file looking for
@c groups USER is a member of.
@end deftypefun
@node Enable/Disable Setuid
@section Enabling and Disabling Setuid Access
A typical setuid program does not need its special access all of the
time. It's a good idea to turn off this access when it isn't needed,
so it can't possibly give unintended access.
If the system supports the saved user ID feature, you can accomplish
this with @code{setuid}. When the game program starts, its real user ID
is @code{jdoe}, its effective user ID is @code{games}, and its saved
user ID is also @code{games}. The program should record both user ID
values once at the beginning, like this:
@smallexample
user_user_id = getuid ();
game_user_id = geteuid ();
@end smallexample
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Then it can turn off game file access with
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@smallexample
setuid (user_user_id);
@end smallexample
@noindent
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and turn it on with
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@smallexample
setuid (game_user_id);
@end smallexample
@noindent
Throughout this process, the real user ID remains @code{jdoe} and the
saved user ID remains @code{games}, so the program can always set its
effective user ID to either one.
On other systems that don't support the saved user ID feature, you can
turn setuid access on and off by using @code{setreuid} to swap the real
and effective user IDs of the process, as follows:
@smallexample
setreuid (geteuid (), getuid ());
@end smallexample
@noindent
This special case is always allowed---it cannot fail.
Why does this have the effect of toggling the setuid access? Suppose a
game program has just started, and its real user ID is @code{jdoe} while
its effective user ID is @code{games}. In this state, the game can
write the scores file. If it swaps the two uids, the real becomes
@code{games} and the effective becomes @code{jdoe}; now the program has
only @code{jdoe} access. Another swap brings @code{games} back to
the effective user ID and restores access to the scores file.
In order to handle both kinds of systems, test for the saved user ID
feature with a preprocessor conditional, like this:
@smallexample
#ifdef _POSIX_SAVED_IDS
setuid (user_user_id);
#else
setreuid (geteuid (), getuid ());
#endif
@end smallexample
@node Setuid Program Example
@section Setuid Program Example
Here's an example showing how to set up a program that changes its
effective user ID.
This is part of a game program called @code{caber-toss} that
manipulates a file @file{scores} that should be writable only by the game
program itself. The program assumes that its executable
file will be installed with the set-user-ID bit set and owned by the
same user as the @file{scores} file. Typically, a system
administrator will set up an account like @code{games} for this purpose.
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The executable file is given mode @code{4755}, so that doing an
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@samp{ls -l} on it produces output like:
@smallexample
-rwsr-xr-x 1 games 184422 Jul 30 15:17 caber-toss
@end smallexample
@noindent
The set-user-ID bit shows up in the file modes as the @samp{s}.
The scores file is given mode @code{644}, and doing an @samp{ls -l} on
it shows:
@smallexample
-rw-r--r-- 1 games 0 Jul 31 15:33 scores
@end smallexample
Here are the parts of the program that show how to set up the changed
user ID. This program is conditionalized so that it makes use of the
saved IDs feature if it is supported, and otherwise uses @code{setreuid}
to swap the effective and real user IDs.
@smallexample
#include <stdio.h>
#include <sys/types.h>
#include <unistd.h>
#include <stdlib.h>
/* @r{Save the effective and real UIDs.} */
static uid_t euid, ruid;
/* @r{Restore the effective UID to its original value.} */
void
do_setuid (void)
@{
int status;
#ifdef _POSIX_SAVED_IDS
status = setuid (euid);
#else
status = setreuid (ruid, euid);
#endif
if (status < 0) @{
fprintf (stderr, "Couldn't set uid.\n");
exit (status);
@}
@}
@group
/* @r{Set the effective UID to the real UID.} */
void
undo_setuid (void)
@{
int status;
#ifdef _POSIX_SAVED_IDS
status = setuid (ruid);
#else
status = setreuid (euid, ruid);
#endif
if (status < 0) @{
fprintf (stderr, "Couldn't set uid.\n");
exit (status);
@}
@}
@end group
/* @r{Main program.} */
int
main (void)
@{
/* @r{Save the real and effective user IDs.} */
ruid = getuid ();
euid = geteuid ();
undo_setuid ();
/* @r{Do the game and record the score.} */
@dots{}
@}
@end smallexample
Notice how the first thing the @code{main} function does is to set the
effective user ID back to the real user ID. This is so that any other
file accesses that are performed while the user is playing the game use
the real user ID for determining permissions. Only when the program
needs to open the scores file does it switch back to the original
effective user ID, like this:
@smallexample
/* @r{Record the score.} */
int
record_score (int score)
@{
FILE *stream;
char *myname;
/* @r{Open the scores file.} */
do_setuid ();
stream = fopen (SCORES_FILE, "a");
undo_setuid ();
@group
/* @r{Write the score to the file.} */
if (stream)
@{
myname = cuserid (NULL);
if (score < 0)
fprintf (stream, "%10s: Couldn't lift the caber.\n", myname);
else
fprintf (stream, "%10s: %d feet.\n", myname, score);
fclose (stream);
return 0;
@}
else
return -1;
@}
@end group
@end smallexample
@node Tips for Setuid
@section Tips for Writing Setuid Programs
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It is easy for setuid programs to give the user access that isn't
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intended---in fact, if you want to avoid this, you need to be careful.
Here are some guidelines for preventing unintended access and
minimizing its consequences when it does occur:
@itemize @bullet
@item
Don't have @code{setuid} programs with privileged user IDs such as
@code{root} unless it is absolutely necessary. If the resource is
specific to your particular program, it's better to define a new,
nonprivileged user ID or group ID just to manage that resource.
@item
Be cautious about using the @code{system} and @code{exec} functions in
combination with changing the effective user ID. Don't let users of
your program execute arbitrary programs under a changed user ID.
Executing a shell is especially bad news. Less obviously, the
@code{execlp} and @code{execvp} functions are a potential risk (since
the program they execute depends on the user's @code{PATH} environment
variable).
If you must @code{exec} another program under a changed ID, specify an
absolute file name (@pxref{File Name Resolution}) for the executable,
and make sure that the protections on that executable and @emph{all}
containing directories are such that ordinary users cannot replace it
with some other program.
@item
Only use the user ID controlling the resource in the part of the program
that actually uses that resource. When you're finished with it, restore
the effective user ID back to the actual user's user ID.
@xref{Enable/Disable Setuid}.
@item
If the @code{setuid} part of your program needs to access other files
besides the controlled resource, it should verify that the real user
would ordinarily have permission to access those files. You can use the
@code{access} function (@pxref{Access Permission}) to check this; it
uses the real user and group IDs, rather than the effective IDs.
@end itemize
@node Who Logged In
@section Identifying Who Logged In
@cindex login name, determining
@cindex user ID, determining
You can use the functions listed in this section to determine the login
name of the user who is running a process, and the name of the user who
logged in the current session. See also the function @code{getuid} and
friends (@pxref{Reading Persona}).
The @code{getlogin} function is declared in @file{unistd.h}, while
@code{cuserid} and @code{L_cuserid} are declared in @file{stdio.h}.
@pindex stdio.h
@pindex unistd.h
@comment unistd.h
@comment POSIX.1
@deftypefun {char *} getlogin (void)
The @code{getlogin} function returns a pointer to a string containing the
name of the user logged in on the controlling terminal of the process,
or a null pointer if this information cannot be determined. The string
is statically allocated and might be overwritten on subsequent calls to
this function or to @code{cuserid}.
@end deftypefun
@comment stdio.h
@comment POSIX.1
@deftypefun {char *} cuserid (char *@var{string})
The @code{cuserid} function returns a pointer to a string containing a
user name associated with the effective ID of the process. If
@var{string} is not a null pointer, it should be an array that can hold
at least @code{L_cuserid} characters; the string is returned in this
array. Otherwise, a pointer to a string in a static area is returned.
This string is statically allocated and might be overwritten on
subsequent calls to this function or to @code{getlogin}.
@end deftypefun
@comment stdio.h
@comment POSIX.1
@deftypevr Macro int L_cuserid
An integer constant that indicates how long an array you might need to
store a user name.
@end deftypevr
These functions let your program identify positively the user who is
running or the user who logged in this session. (These can differ when
setuid programs are involved; @xref{Process Persona}.) The user cannot
do anything to fool these functions.
For most purposes, it is more useful to use the environment variable
@code{LOGNAME} to find out who the user is. This is more flexible
precisely because the user can set @code{LOGNAME} arbitrarily.
@xref{Standard Environment}.
@node User Database
@section User Database
@cindex user database
@cindex password database
@pindex /etc/passwd
This section describes all about how to search and scan the database of
registered users. The database itself is kept in the file
@file{/etc/passwd} on most systems, but on some systems a special
network server gives access to it.
@menu
* User Data Structure:: What each user record contains.
* Lookup User:: How to look for a particular user.
* Scanning All Users:: Scanning the list of all users, one by one.
* Writing a User Entry:: How a program can rewrite a user's record.
@end menu
@node User Data Structure
@subsection The Data Structure that Describes a User
The functions and data structures for accessing the system user database
are declared in the header file @file{pwd.h}.
@pindex pwd.h
@comment pwd.h
@comment POSIX.1
@deftp {Data Type} {struct passwd}
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The @code{passwd} data structure is used to hold information about
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entries in the system user data base. It has at least the following members:
@table @code
@item char *pw_name
The user's login name.
@item char *pw_passwd.
The encrypted password string.
@item uid_t pw_uid
The user ID number.
@item gid_t pw_gid
The user's default group ID number.
@item char *pw_gecos
A string typically containing the user's real name, and possibly other
information such as a phone number.
@item char *pw_dir
The user's home directory, or initial working directory. This might be
a null pointer, in which case the interpretation is system-dependent.
@item char *pw_shell
The user's default shell, or the initial program run when the user logs in.
This might be a null pointer, indicating that the system default should
be used.
@end table
@end deftp
@node Lookup User
@subsection Looking Up One User
@cindex converting user ID to user name
@cindex converting user name to user ID
You can search the system user database for information about a
specific user using @code{getpwuid} or @code{getpwnam}. These
functions are declared in @file{pwd.h}.
@comment pwd.h
@comment POSIX.1
@deftypefun {struct passwd *} getpwuid (uid_t @var{uid})
This function returns a pointer to a statically-allocated structure
containing information about the user whose user ID is @var{uid}. This
structure may be overwritten on subsequent calls to @code{getpwuid}.
A null pointer value indicates there is no user in the data base with
user ID @var{uid}.
@end deftypefun
@comment pwd.h
@comment POSIX.1
@deftypefun {struct passwd *} getpwnam (const char *@var{name})
This function returns a pointer to a statically-allocated structure
containing information about the user whose user name is @var{name}.
This structure may be overwritten on subsequent calls to
@code{getpwnam}.
A null pointer value indicates there is no user named @var{name}.
@end deftypefun
@node Scanning All Users
@subsection Scanning the List of All Users
@cindex scanning the user list
This section explains how a program can read the list of all users in
the system, one user at a time. The functions described here are
declared in @file{pwd.h}.
You can use the @code{fgetpwent} function to read user entries from a
particular file.
@comment pwd.h
@comment SVID
@deftypefun {struct passwd *} fgetpwent (FILE *@var{stream})
This function reads the next user entry from @var{stream} and returns a
pointer to the entry. The structure is statically allocated and is
rewritten on subsequent calls to @code{fgetpwent}. You must copy the
contents of the structure if you wish to save the information.
This stream must correspond to a file in the same format as the standard
password database file. This function comes from System V.
@end deftypefun
The way to scan all the entries in the user database is with
@code{setpwent}, @code{getpwent}, and @code{endpwent}.
@comment pwd.h
@comment SVID, BSD
@deftypefun void setpwent (void)
This function initializes a stream which @code{getpwent} uses to read
the user database.
@end deftypefun
@comment pwd.h
@comment POSIX.1
@deftypefun {struct passwd *} getpwent (void)
The @code{getpwent} function reads the next entry from the stream
initialized by @code{setpwent}. It returns a pointer to the entry. The
structure is statically allocated and is rewritten on subsequent calls
to @code{getpwent}. You must copy the contents of the structure if you
wish to save the information.
@end deftypefun
@comment pwd.h
@comment SVID, BSD
@deftypefun void endpwent (void)
This function closes the internal stream used by @code{getpwent}.
@end deftypefun
@node Writing a User Entry
@subsection Writing a User Entry
@comment pwd.h
@comment SVID
@deftypefun int putpwent (const struct passwd *@var{p}, FILE *@var{stream})
This function writes the user entry @code{*@var{p}} to the stream
@var{stream}, in the format used for the standard user database
file. The return value is zero on success and nonzero on failure.
This function exists for compatibility with SVID. We recommend that you
avoid using it, because it makes sense only on the assumption that the
@code{struct passwd} structure has no members except the standard ones;
on a system which merges the traditional Unix data base with other
extended information about users, adding an entry using this function
would inevitably leave out much of the important information.
The function @code{putpwent} is declared in @file{pwd.h}.
@end deftypefun
@node Group Database
@section Group Database
@cindex group database
@pindex /etc/group
This section describes all about how to search and scan the database of
registered groups. The database itself is kept in the file
@file{/etc/group} on most systems, but on some systems a special network
service provides access to it.
@menu
* Group Data Structure:: What each group record contains.
* Lookup Group:: How to look for a particular group.
* Scanning All Groups:: Scanning the list of all groups.
@end menu
@node Group Data Structure
@subsection The Data Structure for a Group
The functions and data structures for accessing the system group
database are declared in the header file @file{grp.h}.
@pindex grp.h
@comment grp.h
@comment POSIX.1
1996-08-15 01:23:29 +00:00
@deftp {Data Type} {struct group}
1995-02-18 01:27:10 +00:00
The @code{group} structure is used to hold information about an entry in
the system group database. It has at least the following members:
@table @code
@item char *gr_name
The name of the group.
@item gid_t gr_gid
The group ID of the group.
@item char **gr_mem
A vector of pointers to the names of users in the group. Each user name
is a null-terminated string, and the vector itself is terminated by a
null pointer.
@end table
@end deftp
@node Lookup Group
@subsection Looking Up One Group
@cindex converting group name to group ID
@cindex converting group ID to group name
You can search the group database for information about a specific
group using @code{getgrgid} or @code{getgrnam}. These functions are
declared in @file{grp.h}.
@comment grp.h
@comment POSIX.1
@deftypefun {struct group *} getgrgid (gid_t @var{gid})
This function returns a pointer to a statically-allocated structure
containing information about the group whose group ID is @var{gid}.
This structure may be overwritten by subsequent calls to
@code{getgrgid}.
A null pointer indicates there is no group with ID @var{gid}.
@end deftypefun
@comment grp.h
@comment SVID, BSD
@deftypefun {struct group *} getgrnam (const char *@var{name})
This function returns a pointer to a statically-allocated structure
containing information about the group whose group name is @var{name}.
This structure may be overwritten by subsequent calls to
@code{getgrnam}.
A null pointer indicates there is no group named @var{name}.
@end deftypefun
@node Scanning All Groups
@subsection Scanning the List of All Groups
@cindex scanning the group list
This section explains how a program can read the list of all groups in
the system, one group at a time. The functions described here are
declared in @file{grp.h}.
You can use the @code{fgetgrent} function to read group entries from a
particular file.
@comment grp.h
@comment SVID
@deftypefun {struct group *} fgetgrent (FILE *@var{stream})
The @code{fgetgrent} function reads the next entry from @var{stream}.
It returns a pointer to the entry. The structure is statically
allocated and is rewritten on subsequent calls to @code{fgetgrent}. You
must copy the contents of the structure if you wish to save the
information.
The stream must correspond to a file in the same format as the standard
group database file.
@end deftypefun
The way to scan all the entries in the group database is with
@code{setgrent}, @code{getgrent}, and @code{endgrent}.
@comment grp.h
@comment SVID, BSD
@deftypefun void setgrent (void)
This function initializes a stream for reading from the group data base.
You use this stream by calling @code{getgrent}.
@end deftypefun
@comment grp.h
@comment SVID, BSD
@deftypefun {struct group *} getgrent (void)
The @code{getgrent} function reads the next entry from the stream
initialized by @code{setgrent}. It returns a pointer to the entry. The
structure is statically allocated and is rewritten on subsequent calls
to @code{getgrent}. You must copy the contents of the structure if you
wish to save the information.
@end deftypefun
@comment grp.h
@comment SVID, BSD
@deftypefun void endgrent (void)
This function closes the internal stream used by @code{getgrent}.
@end deftypefun
@node Database Example
@section User and Group Database Example
Here is an example program showing the use of the system database inquiry
functions. The program prints some information about the user running
the program.
@smallexample
@include db.c.texi
@end smallexample
Here is some output from this program:
@smallexample
I am Throckmorton Snurd.
My login name is snurd.
My uid is 31093.
My home directory is /home/fsg/snurd.
My default shell is /bin/sh.
My default group is guest (12).
The members of this group are:
friedman
tami
@end smallexample