Fall 2013 - September to December 2013 - Updated 2019-03-01 03:58 EST
Unix/Linux has always been a multi-user operating system. (Microsoft Windows didn’t become a multi-user operating system until the merge with Windows NT, somewhere around Windows XP?)
Processes belonging to different users have restrictions on how they can interact with each other and with the file system. Files belong to different users, and users can control how processes run by themselves and other users access their files.
The Unix multi-user system provides security among users and between the system and users. The Unix operating system can protect itself against programs run by ordinary users, so the rare Unix viruses and trojans only affect a single user on a system, not the whole system.
The super-user account
root
on a Unix system can bypass and over-ride all read/write and access permissions. The super-user can access and do anything to any inode. In this document, we discuss permissions as they apply to ordinary, non-root
users.
Each logged-in Unix user is assigned one unique numeric user ID and one or more numeric group IDs. (Group IDs may be shared with other users.) The unique user ID and each group ID are internally stored as numbers.
/etc/passwd
Group file: /etc/group
IndexThe password file and the group file are used to map the numbers to human-friendly names.
The password file
/etc/passwd
maps a user ID number to a name. The group file/etc/group
maps each group ID number to a name. The name is a convenience for people; the processes calculate permissions based on the numeric IDs.User IDs may also be known as userids or uids. Group IDs may also be known as groupids or gids.
You can easily change the name of a user or a group by changing its name in the password or group files. There are privileged system commands that safely do this for you, e.g.
usermod
andgroupmod
.
At login, the password file looks up your login user ID and determines your numeric user ID and one initial group user ID. The group file then assigns to you your other group IDs (if any). The system then starts up a shell that runs as your unique numeric user ID and also has the permissions of all your numeric group IDs (one or more).
Almost all the commands that you run from the shell inherit your user ID and your one or more group IDs. The processes appear to run as “you”.
whoami
, groups
, id
IndexThe whoami
command shows the name of the current user ID, as recorded in the /etc/passwd
file. The groups
command shows the names of the groups of the current user or another user, as recorded in the /etc/group
file:
$ whoami
idallen
$ groups
idallen admin
$ groups root
root bin daemon sys adm disk wheel
The id
command shows both the name and internal number of the user ID and the names and internal numbers of the groups of the current user or another user:
$ id
uid=777(idallen) gid=777(idallen) groups=777(idallen),120(admin)
$ id root
uid=0(root) gid=0(root) groups=0(root),1(bin),2(daemon),3(sys),4(adm),6(disk),10(wheel)
The mapping between numbers and names is done by the password and group files.
Each process (including your shell and each command and process that you run from your shell) runs with the permissions of your single numeric user ID and your one or more numeric group IDs. These numbers are assigned to you when you log in and are passed to most commands when you run them.
For example, when you execute the cp
command, the executing cp
process inherits your numeric user and group IDs from your shell. The cp
command can only perform actions consistent with permissions granted to your user ID and group(s).
If someone else executes the very same cp
command, their running copy will execute using their numeric user and their group IDs.
See below for special setuid and setgid programs that do not inherit your user IDs when you run them. Appendix: Programs with special privileges: setuid / setgid
File system inodes (e.g. files and directories) are owned by one user ID (the “owner”) and belong to only one group (the “group”). (Kernel extensions can expand this restriction.) The owner and group are stored in the inode as internal numbers; the password and group files are used to map the numbers to human-friendly names.
The ls
command uses the password and group files to show you the name of the owner and name of the group for each file system inode (the third and fourth fields in the output below):
$ ls -ld / /dev/mem /etc/shadow /home/idallen /var/log/auth.log
drwxr-xr-x 26 root root 4096 Oct 26 02:16 /
crw-r----- 1 root kmem 1, 1 Oct 26 04:45 /dev/mem
-rw-r----- 1 root shadow 46616 Oct 25 21:32 /etc/shadow
drwxr-x--x 44 idallen idallen 4096 Oct 27 19:59 /home/idallen
-rw-r----- 1 syslog root 52902850 Oct 28 00:41 /var/log/auth.log
It is important to know that the owner and group are stored in each inode as numbers, not names. The password and group files are necessary to turn the stored numbers into human-friendly names.
Changing a user name or group name in the password or group files (requires root
privileges) will change the names displayed by ls
:
$ tail -n 1 /etc/group
test:x:3234:
$ ls -l foo
-rw-r--r-- 1 root test 29 Oct 25 07:05 foo
$ sudo groupmod -n newtest test # rename group "test" to "newtest"
$ tail -n 1 /etc/group
newtest:x:3234:
$ ls -l foo
-rw-r--r-- 1 root newtest 29 Oct 25 07:05 foo
Changing the password or group files affects the output of ls
, because ls
uses these files to map the internal user ID and group ID numbers in the inodes to human-friendly names.
If an internal owner or group number in an inode can’t be mapped to a human-friendly name by ls
(because there is no name for the internal number found in the password or group file), ls
will simply show the internal number in its output:
$ sudo groupdel newtest # delete group "newtest"
$ ls -l foo
-rw-r--r-- 1 root 3234 29 Oct 25 07:05 foo
You often see numbers in the output of
ls
when you mount an external disk that comes from some other system – the internal numbers on that disk don’t correspond to your current password and group files and so many of the owner and group numbers in the inodes on the external disk won’t have matches, and many of the matches on the external disk may map to incorrect names.
Without the password and group files, there is no way to know the human-friendly names of the owner and group numbers stored in the inodes.
You, when you log in, and any process you run, have the permissions of one user ID and one or more groups simultaneously (many groups):
$ id
uid=777(idallen) gid=777(idallen) groups=777(idallen),4(admin)
In the Unix file system, each inode, whether it is a file inode, a directory inode, or some other kind of inode, can be “owned” by exactly one Unix user ID and be in exactly one Unix group (single group):
$ ls -l /etc/passwd
-rw-r--r-- 1 root root 2458 Nov 18 01:17 /etc/passwd
Processes (run by users) can have many groups; file system inodes can have only one group.
When a process tries to read or write any kind of file system inode (a file, a directory, or some other file system object), the meshing of the user and group IDs of the process and the owner and group IDs set in the inode determine if the access succeeds.
What a process can do to a file system inode – what permissions it has on the inode – is determined by how the process user ID and any of its many groups mesh with the single owner/userid and single group ID of the inode in the file system.
The word mode is often used in Unix to talk about the permissions of a file system inode. The term mode means “file system inode permissions”. We often casually say “file” mode, but permissions apply to each inode whether it is a file, directory, or something else.
ls -l
to display the symbolic mode of an inodeIndexEach file system inode has room in its mode to store three sets of three Unix permissions (nine permissions in total). These three sets of three permissions stored in the inode control which processes can read or modify the inode.
The three sets are named user (owner), group, and other permissions, abbreviated u
, g
, and o
. Note that user permissions are sometimes called owner permissions, but the abbreviation is always u
for user.
Each set itself contains three possible permissions, named read, write, and execute/search, abbreviated r
, w
, and x
. Note that search permission is still abbreviated as x
.
Three sets of three permissions gives a total of nine permissions. The ls
command displays these nine permissions in symbolic form as three sets of three rwx
letters and/or and dashes near the start of a long listing:
$ ls -ld filename dirname symlink
-rw-r----- 1 user1 group1 123 Nov 12 14:14 filename
drwxr-x--x 1 user2 group2 123 Nov 12 14:14 dirname
lrwxrwxrwx 1 root root 123 Nov 12 14:14 symlink -> target
The first character in the ls -ld
listing above is the type of the inode (it is not part of the nine permissions). Common type character values are:
-
: a dash/hyphen/minus indicates that the inode is a plain filed
: indicates that this inode is a directoryl
: (lower-case L
) indicates a symbolic link (permissions are ignored)The nine characters after the type character are the Mode or Permissions of the inode. There are three sets of three possible rwx
permissions, one set of three for each of user, group, and other:
d
rwxr-x--x
– type field: d
is a directoryd
rwx
r-x--x
– user permissions (first three rwx
)drwx
r-x
--x
– group permissions (second three r-x
)drwxr-x
--x
– other permissions (last three --x
)The three characters in a set are always displayed as three characters, in rwx
order. In each set of three permission characters, a hyphen/minus/dash character -
replaces a letter if the corresponding permission is not granted in that set, e.g.
rwx
means read, write, and execute/search permissions are grantedrw-
means only read and write permissions are grantedr--
means only read permission is granted--x
means only execute/search permission is granted---
means no permissions are grantedA hyphen/minus/dash in any of the three positions means NO permission, so ---
means no read, no write, and no execute (no permissions at all) for that type of permission on this file inode.
Here is what happens when a Unix process (running as some user ID and with some set of group IDs) tries to access a Unix file system inode:
User Permissions: If the unique user ID of the process doing the access matches the user ID that owns the inode, the three permissions in the user (owner) permissions field of the inode determines whether or not the access succeeds. (The user/owner permissions are the first set of three permissions letters in the output of ls -l
.)
If the user IDs do not match, move to part #2:
Group Permissions: (Only done if the user IDs do not match:) If any of the several group IDs of the process doing the access match the single group ID of the inode, the three permissions in the group permissions field of the inode determines whether or not the access succeeds. (The group permissions are the second set of three permissions letters in the output of ls -l
.)
If the group IDs do not match, move to part #3:
Other Permissions: (Only done if both the user IDs and group IDs do not match:) The three permissions in the other permissions field determines whether or not the access succeeds. (The other permissions are the last, rightmost, set of three permissions letters in the output of ls -l
.)
Note that if the user IDs match, those are the only permissions used, even if those permissions deny access. The same applies to a group match. It is not true that the system will try group or other permissions if the user ID or group permissions deny access. Once a set of permissions is chosen, they are the only permissions used. Yes, you can create inodes where the owner can’t read the data but everyone else can.
Given this file:
$ ls -ld filename
-rw-r----x 1 user1 group1 123 Nov 12 14:14 filename
rw-
of the nine-character mode are the three permissions that apply to any process where the user ID of the process matches the user (owner) of the inode.r--
of the nine are the three permissions that apply to processes where the users do not match but any one of the process group IDs matches the group of the inode.--x
of the nine are the three permissions that apply to everyone else (processes that are not running as the user/owner of the inode and none of the groups match).Above, the file filename
has mode rw-
(read, write, NO execute) for user ID user1
, mode r--
(read only) for anyone with group ID group1
, and --x
(execute only) for everyone else (not user1
and not in group1
).
rwx
IndexIn each of the above three sets of permissions – user, group, and other – three permissions can be controlled: Read permission, Write permission, and eXecute/search permission. Recall that these three sets of three permissions appear as the letters rwx
in the output from ls -l
:
$ ls -l /bin/ls
-rwxr-xr-x 1 root root 105840 Nov 19 2016 /bin/ls
The user ID and group ID(s) of the process are matched against the user ID and group ID of the inode to determine which of the three sets of permissions apply: user, group, or other. Once a set is chosen, the rwx
permissions are used to limit what the process can do to that inode:
r--
IndexThe process can read the data in the inode. For a file, the process can read the data contained in the file. For a directory, the process can read only the names contained in the directory.
Read permission on a directory only gives the process access to the names in the directory itself. (The process needs further permission to follow the inode numbers to have access to the actual inodes and content of the items named in the directory. You may be able to see a file’s name but not have permission to see the file’s owner or contents.)
-w-
IndexThe process can write to the inode. For a file, this means that the process can alter the data contained in the file. For a directory (which only contains names and inode numbers), the process can add, remove, or alter (rename) the names in the directory.
Write permission on a directory only gives the process the ability to change the names in the directory. (The process may not have permission to alter the data in the inodes of the items named in the directory. You may be able to rename or delete a file name but not have permissions to read or write the file data itself.)
--x
IndexFor a file, the process may load the binary image of the file into memory and execute it. If the file is executable but not binary, i.e. a script file, it is the program specified in the #!
line at the top of the script file that is loaded into memory instead.
For a directory, the process may “pass through” the directory to access the inode numbers and content of the items named in the directory. Without search permissions on a directory, the process cannot access any of the inodes and content named in the directory.
One exception to permissions and modes is symbolic links: The permissions on any symbolic link inode are always rwxrwxrwx
and are always ignored and can’t be changed. You can safely ignore the permissions, user, and group of symbolic links.
rwx
permissionsIndexEach of the three sets of three permissions contains three characters indicating which of these three permissions is allowed for each set:
r
– means read permission (can access the content of the inode)w
– means write permission (can change the content of the inode)x
– means execute permission for file inodes and search or access permission for directory inodesSome important notes on a set of three rwx
permissions:
rwx
order, never wxr
or xwr
-
) e.g. r-x
, --x
, r--
, etc., never as rx
, x
, or r
.chmod
command allows you to leave out the -
when changing permissions, e.g. chmod u=rx
For a directory, execute x
permission is search or access permission and it means a process may “pass through” or “access” the directory to access the inode numbers and content of the items named in the directory.
If you have only r--
permissions on a directory (only read permissions), you can only see the names in the directory; you cannot “pass through” the directory to the inodes of the things named in the directory. You cannot find out the kind of things to which the names are attached (unless your brand of Linux caches that information in the directory), nor can you access the content of those things. You only have permission to see the names in the directory, not to use them. ls
works, but not ls -l
that requires access to the inodes of the items in the directory to find out what kinds of things they are and other information:
$ ls dir
x y z
$ ls -l dir
ls: cannot access dir/x: Permission denied
ls: cannot access dir/z: Permission denied
ls: cannot access dir/y: Permission denied
If you have only --x
permissions on a directory (only search permissions), you can “pass through” the directory to the inodes of anything contained in the directory; but, you cannot read any of the names in the directory. You have permissions to use the names, not to see them. (Of course, the only way you can use a name that you can’t see is if you already know that the name is in the directory.)
$ cat dir/date
Tue Oct 25 11:07:42 EDT 2016
$ ls dir
ls: cannot access dir: Permission denied
A directory with -wx
permissions lets a process enter or change names in it; but, without read permissions, the process cannot read the names back from the directory. (If the names are random and guaranteed unique, it’s a form of digital “drop box” where items can be created and written by any process but whose names cannot be snooped by other processes.)
A directory with only -w-
permissions is useless, though you might think it would permit you to create new names or to rename existing names if you know them. The implementation is such that any action that requires write permission on a directory also requires search permission. (Consider that any action that writes a name in a directory also has to have access to the inode of the thing being named, and that inode access requires search permissions on the directory.) Similarly, having rw-
permissions is the same as r--
permissions; without search permissions, write permissions don’t work.
You need search permission as well as write permission on a directory to be able to create, remove, or change names in the directory.
(You do not also need execute permission to write on a file. For a file, write permission is all you need to write on it.)
The permissions that govern access to the things listed a directory are stored in the inode for that directory. Without access permissions on a directory, you can’t access anything inside that directory.
The permissions for the actual items named in the directory are not kept in the directory. The permissions on the things are stored in the inodes for the items being named.
Because names are stored separately from the things they name, the permissions you may have to alter the names in the directory are not the same as the permissions you have to alter the contents the actual things being named.
Changing the permissions of a directory only affects what you can do to the name of the thing stored directory; it doesn’t directly affect what you can do to the actual content of the things named in the directory. You may be able to write the inode of the directory but unable to write the inodes of anything named in the directory, or vice-versa.
You may have a directory that you can modify (rwx
) that contains names for things that you cannot even read (---
). You can rename the things or remove their names from your directory; but, you cannot read the things or change them in any way.
You may have a directory that you cannot modify (r-x
) that contains names for things that you have full permissions to modify (rw-
). You have full permissions to modify the item named in the directory; but, you cannot remove its name from the directory or change its name (because you cannot write the directory where the name is kept).
Names of things are stored in directories; directories have separate permissions from the things being names.
Unix directories are very simple; they only contain names and inode numbers. Nothing in a directory directly controls what access permissions a process has to Unix file system inodes that are named in that directory. (The permissions on the directory itself may prevent some process from getting to an inode using that directory; but, once the process gets to the inode, it is the permissions stored in that inode that apply. No permissions on that inode are stored up in the directory itself.)
To determine what access permissions a process has on some Unix file system object, the process must use the object’s name to pass through the directory and go to the actual inode for the object. Permissions for the object (e.g. a file) are not kept in the directory; they are kept in the inode for the object. Only the object’s name and inode number are kept up in the directory.
The inode containing the permissions for an object is separate from the directory inode containing the name of the object. To access an object, a process needs to pass through the directory (it must have “search permission” on the directory inode) and then have appropriate permissions on the inode that is the object itself.
/etc/passwd
IndexThe pathname /etc/passwd
refers to two directories and one file. To know how your account and groups can access this file, you need to look at the permissions on the two directories and on the file itself:
$ ls -ld /
drwxr-xr-x 24 root root 4096 Nov 24 16:51 /
$ ls -ld /etc
drwxr-xr-x 180 root root 12288 Feb 29 13:38 /etc
$ ls -l /etc/passwd
-rw-r--r-- 1 root root 2209 Jan 19 20:39 /etc/passwd
$ id
uid=777(idallen) gid=777(idallen) groups=777(idallen),120(admin)
The current login user ID idallen
and the current group idallen
do not match the owner or group of ROOT, /etc
, or /etc/passwd
, which means that other permissions apply to both directories and to the file itself:
r-x
permissions on ROOT allow /etc
to be reached (search ok).r-x
permissions on /etc
allow /etc/passwd
to be reached (search ok).r--
permissions on /etc/passwd
allow the content to be read.One could prevent access to this file by removing other permissions from any of the three inodes in the pathname. (Removing permissions from the ROOT or /etc
directories would prevent access to huge numbers of other files and directories and may prevent the system from working properly!)
Summary: All the directories leading to a pathname need to have search permissions enabled. The permissions on the final pathname component (the basename) must allow the desired access.
chmod
IndexThe owner of an inode is the only one who can change the mode (permissions) of an inode. The owner can always change the mode of the inode, even if the inode has no permissions for the owner. (So the owner of an inode can always restore full permissions to access the inode.)
Only the user/owner of an inode can change its permissions, even if the inode has full permissions for other groups or other users. Nobody can change the mode except the owner of the inode.
Use the chmod
(change mode) command to change the permissions (RTFM):
chmod mode pathnames...
You must supply at least two arguments:
Examples of setting or adding/removing permissions on a pathname:
chmod u=rwx,g=rx,o=wx path # set inode to rwxr-x-wx or 753 octal
chmod 753 path # set to 753 or rwxr-x-wx symbolic
chmod u+r path # add only owner read permission; leave wx unchanged
chmod go-wx path # remove only group and other wx permissions; leave r unchanged
The mode argument can be either octal-numeric or symbolic, as shown above. For an explanation of octal-numeric modes, see octal permissions.
The chmod
command follows symbolic links given on the command line and changes the target that the link points to. It never changes the permissions on the symlink itself.
+
or -
IndexNote that adding or removing permissions using symbolic permissions with the +
or -
operators (e.g. u+r
, go-rx
) leaves the other unspecified permissions unchanged.
Adding and removing permissions only works for symbolic permissions and only affects the given permissions and doesn’t change any of the other unspecified permissions. Octal/numeric permissions always set all nine of the permissions; you can’t leave any unchanged. Symbolic permissions set with =
also change all of the permissions; you can’t use =
to add or remove permissions.
Adding and removing permissions using the symbolic +
or -
operators (e.g. u+r
, go-rx
) is very common, since usually you don’t want to set or change any of the other existing permissions.
For example, to add other read permission to all non-hidden inodes in the current directory, use chmod o+r *
not chmod o=r *
because the latter would take away existing w
or x
permissions, which would make a directory inaccessible.
When a file system is damaged and a directory inode is lost, the only things that go missing are the names of the items in the directory.
Everything else about the items – the permissions, owner, group, modify time, size, etc. – is not lost; it is stored in the items’ inodes, separate from the lost directory inode. A damaged directory only loses names, not data. Permissions are not affected.
When you create a hard link to a file, you create another name in a directory for the file’s unique inode number. Since the file permissions are stored with the file’s inode, not in the directory, all the names for a file lead to the same inode and thus to the same permissions.
Changing the permissions of a file using one of the hard-linked names changes the permissions for the inode and thus for all the names; all the names lead to the same unique inode and the same permissions.
Hard-linked names cannot have different owners, groups, or permissions; both names lead to the same inode.
Creating a name for an existing inode (ln
), renaming (mv
), or removing a name (a hard link) (rm
) are all directory operations. The permissions on the directory inode apply, not the permissions on the inode of the thing to which you are making a link. You can create in your own directory a hard link to a file even if you have no permissions to read the file itself. You can remove or rename the name of a file in your directory if you have permission on the directory; you don’t need any permissions at all on the inode of the file itself.
Recent versions of the Linux kernel (since 3.6) have created a new kernel security option that, when enabled, prevents you from making a hard link to (new name for) a file that you do not own and cannot read or write. See the kernel
sysctl
optionfs.protected_hardlinks
or entry/proc/sys/fs/protected_hardlinks
in the man pageproc(5)
. This Linux course assumes that this option is not enabled, so that you can create a hard link to any file you can access in the current file system without restriction.
ls
on the current directory: ls .
IndexWhat permissions are needed to list the contents of the current directory (i.e. using ls
that really means ls .
)?
The current directory is only accessible using the name dot (“.
”). To get a listing of the contents of the current directory, you must first have permission to use the name dot .
in the current directory to get to the current directory. The name dot .
is itself stored in the current directory. To use (“pass through to”) any name in a directory, you must have search permissions on the directory; so, you must have at least --x
permission on the current directory to use the name dot .
in the current directory.
Once you have used dot .
to get to the inode that is the current directory, you must be able to read the names from the directory to generate a listing of its contents for ls
. Reading the names in a directory requires at least read permission on the directory (r--
).
Thus, to get a listing of the current directory, on the directory you must have both search permissions (to use the name dot .
) and read permissions (to get a list of the names in the directory). Result – you need: r-x
permissions to get the listing.
Without search permissions, you cannot use the name dot (“.
”). Without read permissions, you cannot get a list of the names in the directory. You need both.
$ pwd
/home/idallen
$ mkdir new
$ ls -l new
total 0
$ ls -ld new
drwxrwxr-x 2 idallen idallen 4096 2016-02-29 05:21 new
$ touch new/{a,b,c}
$ cd new
$ ls
a b c
$ chmod u-x . # remove search permission; leave read perms
$ ls
ls: cannot open directory .: Permission denied
$ ls ..
ls: cannot access ..: Permission denied
$ ls /home/idallen/new
a b c
$ chmod u+x .
chmod: cannot access '.': Permission denied
$ chmod u+x /home/idallen/new
$ ls
a b c
If you use the absolute pathname of the directory, you only need read permissions on a directory to see the names in it, because you are not needing to use the name dot .
inside the directory to get to the directory. In other words: To see the names in a directory from inside the directory means the directory needs r-x
permissions; to see the same thing using an absolute path to the directory needs only r--
permissions on the directory.
What permissions are set on directory dir
, below?
$ unalias ls
$ ls dir
x y z
$ ls -l dir
ls: cannot access dir/x: Permission denied
ls: cannot access dir/z: Permission denied
ls: cannot access dir/y: Permission denied
total 0
-????????? ? ? ? ? ? x
-????????? ? ? ? ? ? y
-????????? ? ? ? ? ? z
Answer: Read permissions but not search (eXecute) permissions.
The ls
command without any options simply lists the names in the directory. This only requires read permissions on the directory to read the names. The simple ls
with no options succeeded; the directory had read permissions.
With the -l
option, ls -l
must use each name in the directory to access the inode associated with that name to find out the permissions, owner, group, times, etc. for that inode. To use a name – to “search” or “pass through” a directory – requires search (eXecute) permissions on the directory, which were not enabled. For each name in the directory, the permission to access dir/name
for the long listing was denied.
The directory had read permissions but no search permissions. We can see the names, but we are not allowed to use the names to find out anything about the objects being named.
NOTE: Careful observers will note that the
ls -l
command did know the file inode type of each of the files – the first character in each line of output is a dash, not a question mark. Modern Unix/Linux systems cache some of the inode information in the directory so that commands such asls
don’t have to make a disk access every time just to find out what kind of inode each name is.
Given the following inode permissions on these things:
---x------ 1 dar staff 123 Apr 1 2016 dar1
----rwxrwx 1 dar cst8207 512 Apr 1 2016 dar2
dr---wx-w- 1 dar cst8207 512 Apr 1 2016 dar3
-r---wx-w- 1 les cst8207 123 Apr 1 2016 les1
drwxrw-r-x 1 les alumni 512 Apr 1 2016 les2
-rwxrw-r-x 1 pat alumni 123 Apr 1 2016 pat1
d--x------ 1 pat staff 512 Apr 1 2016 pat2
-rw-r--r-- 1 root system 123 Apr 1 2016 root1
drwx----wx 1 root system 512 Apr 1 2016 root2
And given these users and their user IDs and group IDs:
root - super user
dar - in groups "alumni" and "cst8207"
les - in groups "alumni" and "staff"
pat - in groups "student" and "cst8207"
kai - in groups "alumni" and "system"
tam - in groups "system" and "staff"
dod - in groups "nobody"
Answer these questions:
What type of inode is each thing above? (directory, file, other…)
For files, what permissions do each of the users have on each file inode?
For directories, what permissions do each of the users have on each directory inode?
dar
has no permissions on file dar2
, because user dar
matches inode owner dar
and owner permissions are ---
. Because the user/owner permissions match, the system does not try group or other permissions.dar
can only read the names in directory dar3
, because user dar
matches inode owner dar
and owner permissions are r--
. Because the user/owner permissions match, the system does not try group or other permissions.Normally when you execute a program, the program inherits your user ID and your group IDs from your shell and the program runs “as you” and has your permissions.
A very few program executable files are set up on Unix to execute using the user ID and/or group ID of the file inode of the program; they do not inherit from the person running the program. These program files are called either setuid (set user ID) or setgid (set group ID) programs. Typically, these are privileged programs that need to create or modify files in directories where ordinary users cannot write. They also may need special permissions to access network resources.
Setuid and setgid programs show up with the s
bit set (instead of x
) in the owner and/or group permissions field in the output of a ls -l
listing:
$ ls -l /bin/su /bin/ping /bin/umount /bin/mount
-rwsr-xr-x root root 36832 Sep 12 2016 /bin/su
-rwsr-xr-x root root 35712 Nov 8 2016 /bin/ping
-rwsr-xr-x root root 69096 Mar 30 2016 /bin/umount
-rwsr-xr-x root root 94792 Mar 30 2016 /bin/mount
The above setuid programs (rws
) do not take on the user ID of the person who runs them; the programs always run with the privileges of the root
account that is the owner of the file inode.
$ ls -l /sbin/unix_chkpwd
-rwxr-sr-x 1 root shadow 35432 Feb 8 2016 unix_chkpwd
The above setgid program (r-s
) does not take on the group ID of the person who runs it; the program always runs with the group privileges of the shadow
group account that is the group of the file.
$ ls -l /usr/bin/at
-rwsr-sr-x 1 daemon daemon 51464 Jan 14 2016 /usr/bin/at
The above program is both setuid (rws
) and setgid (r-s
). It runs with the privileges of user ID daemon
and group ID daemon
.
Only the owner of an inode can change its mode (permissions), and that includes making its program file setuid or setgid.
A poorly written setuid file may be a security problem. With its elevated privileges, the setuid file may be exploited to damage the system. Looking for unusual setuid programs is part of a system security check.