&author.jht;
&author.jeremy;
&person.jelmer;drawingMay 10, 2003File, Directory, and Share Access ControlsACLssharenetwork access controlsunauthorized access
Advanced MS Windows users are frequently perplexed when file, directory, and share manipulation of
resources shared via Samba do not behave in the manner they might expect. MS Windows network
administrators are often confused regarding network access controls and how to
provide users with the access they need while protecting resources from unauthorized access.
file access permissionsdirectory access permissions
Many UNIX administrators are unfamiliar with the MS Windows environment and in particular
have difficulty in visualizing what the MS Windows user wishes to achieve in attempts to set file
and directory access permissions.
bridgedirectory controlsdirectory permissions
The problem lies in the differences in how file and directory permissions and controls work
between the two environments. This difference is one that Samba cannot completely hide, even
though it does try to bridge the chasm to a degree.
Extended AttributesACLsPOSIXAccess Control Listcommercial Linux products
POSIX Access Control List technology has been available (along with extended attributes)
for UNIX for many years, yet there is little evidence today of any significant use. This
explains to some extent the slow adoption of ACLs into commercial Linux products. MS Windows
administrators are astounded at this, given that ACLs were a foundational capability of the now
decade-old MS Windows NT operating system.
network administrator
The purpose of this chapter is to present each of the points of control that are possible with
Samba in the hope that this will help the network administrator to find the optimum method
for delivering the best environment for MS Windows desktop users.
interoperabilitydata interchange
This is an opportune point to mention that Samba was created to provide a means of interoperability
and interchange of data between differing operating environments. Samba has no intent to change
UNIX/Linux into a platform like MS Windows. Instead the purpose was and is to provide a sufficient
level of exchange of data between the two environments. What is available today extends well
beyond early plans and expectations, yet the gap continues to shrink.
Features and Benefits
Samba offers much flexibility in file system access management. These are the key access control
facilities present in Samba today:
Samba Access Control FacilitiespermissionsUNIX file and directoryUNIX File and Directory PermissionsUNIX file system access controlsaccess controlspermissions and controls
Samba honors and implements UNIX file system access controls. Users
who access a Samba server will do so as a particular MS Windows user.
This information is passed to the Samba server as part of the logon or
connection setup process. Samba uses this user identity to validate
whether or not the user should be given access to file system resources
(files and directories). This chapter provides an overview for those
to whom the UNIX permissions and controls are a little strange or unknown.
Samba Share Definitionsshare settings
In configuring share settings and controls in the &smb.conf; file,
the network administrator can exercise overrides to native file
system permissions and behaviors. This can be handy and convenient
to effect behavior that is more like what MS Windows NT users expect,
but it is seldom the best way to achieve this.
The basic options and techniques are described herein.
Samba Share ACLsACLsshareACLs on shares
Just as it is possible in MS Windows NT to set ACLs on shares
themselves, so it is possible to do in Samba.
Few people make use of this facility, yet it remains one of the
easiest ways to affect access controls (restrictions) and can often
do so with minimum invasiveness compared with other methods.
ACLsPOSIXACLsWindowsMS Windows ACLs through UNIX POSIX ACLsnative ACLs
The use of POSIX ACLs on UNIX/Linux is possible only if the underlying
operating system supports them. If not, then this option will not be
available to you. Current UNIX technology platforms have native support
for POSIX ACLs. There are patches for the Linux kernel that also provide
this support. Sadly, few Linux platforms ship today with native ACLs and
extended attributes enabled. This chapter has pertinent information
for users of platforms that support them.
File System Access Controls
Perhaps the most important recognition to be made is the simple fact that MS Windows NT4/200x/XP
implement a totally divergent file system technology from what is provided in the UNIX operating system
environment. First we consider what the most significant differences are, then we look
at how Samba helps to bridge the differences.
MS Windows NTFS Comparison with UNIX File SystemsNTFSFile SystemFile SystemUNIXFile SystemWindows
Samba operates on top of the UNIX file system. This means it is subject to UNIX file system conventions
and permissions. It also means that if the MS Windows networking environment requires file system
behavior, that differs from UNIX file system behavior then somehow Samba is responsible for emulating
that in a transparent and consistent manner.
It is good news that Samba does this to a large extent, and on top of that, provides a high degree
of optional configuration to override the default behavior. We look at some of these overrides,
but for the greater part we stay within the bounds of default behavior. Those wishing to explore
the depths of control ability should review the &smb.conf; man page.
The following compares file system features for UNIX with those of MS Windows NT/200x:
File Systemfeature comparisonName Space
MS Windows NT4/200x/XP file names may be up to 254 characters long, and UNIX file names
may be 1023 characters long. In MS Windows, file extensions indicate particular file types;
in UNIX this is not so rigorously observed because all names are considered arbitrary.
What MS Windows calls a folder, UNIX calls a directory.
Case Sensitivity8.3 file namesFile Systemcase sensitivity
MS Windows file names are generally uppercase if made up of 8.3 (8-character file name
and 3 character extension. File names that are longer than 8.3 are case preserving and case
insensitive.
UNIX file and directory names are case sensitive and case preserving. Samba implements the
MS Windows file name behavior, but it does so as a user application. The UNIX file system
provides no mechanism to perform case-insensitive file name lookups. MS Windows does this
by default. This means that Samba has to carry the processing overhead to provide features
that are not native to the UNIX operating system environment.
Consider the following. All are unique UNIX names but one single MS Windows file name:
MYFILE.TXT
MyFile.txt
myfile.txt
So clearly, in an MS Windows file namespace these three files cannot co-exist, but in UNIX
they can.
So what should Samba do if all three are present? That which is lexically first will be
accessible to MS Windows users; the others are invisible and unaccessible &smbmdash; any
other solution would be suicidal. The Windows client will ask for a case-insensitive file
lookup, and that is the reason for which Samba must offer a consistent selection in the
event that the UNIX directory contains multiple files that would match a case insensitive
file listing.
Directory SeparatorsDirectory Separators
MS Windows and DOS use the backslash \ as a directory delimiter, and UNIX uses
the forward-slash / as its directory delimiter. This is handled transparently by Samba.
Drive IdentificationDrive Identification
MS Windows products support a notion of drive letters, like C:, to represent
disk partitions. UNIX has no concept of separate identifiers for file partitions; each
such file system is mounted to become part of the overall directory tree.
The UNIX directory tree begins at / just as the root of a DOS drive is specified as
C:\.
File Naming ConventionsFile Naming Conventions
MS Windows generally never experiences file names that begin with a dot (.), while in UNIX these
are commonly found in a user's home directory. Files that begin with a dot (.) are typically
startup files for various UNIX applications, or they may be files that contain
startup configuration data.
Links and Short-CutsLinkshardLinkssoftShortcuts
MS Windows make use of links and shortcuts that are actually special types of files that will
redirect an attempt to execute the file to the real location of the file. UNIX knows of file and directory
links, but they are entirely different from what MS Windows users are used to.
Symbolic links are files in UNIX that contain the actual location of the data (file or directory). An
operation (like read or write) will operate directly on the file referenced. Symbolic links are also
referred to as soft links. A hard link is something that MS Windows is not familiar with. It allows
one physical file to be known simultaneously by more than one file name.
There are many other subtle differences that may cause the MS Windows administrator some temporary discomfort
in the process of becoming familiar with UNIX/Linux. These are best left for a text that is dedicated to the
purpose of UNIX/Linux training and education.
Managing Directoriescreatedeleterename
There are three basic operations for managing directories: create, delete,
rename. Managing Directories with UNIX and
Windows compares the commands in Windows and UNIX that implement these operations.
Managing Directories with UNIX and WindowsActionMS Windows CommandUNIX Commandcreatemd foldermkdir folderdeleterd folderrmdir folderrenamerename oldname newnamemv oldname newname
File and Directory Access ControlACLsFile SystemPOSIX ACLsEAs
The network administrator is strongly advised to read basic UNIX training manuals and reference materials
regarding file and directory permissions maintenance. Much can be achieved with the basic UNIX permissions
without having to resort to more complex facilities like POSIX ACLs or extended attributes (EAs).
UNIX/Linux file and directory access permissions involves setting three primary sets of data and one control set.
A UNIX file listing looks as follows:
&prompt;ls -la
total 632
drwxr-xr-x 13 maryo gnomes 816 2003-05-12 22:56 .
drwxrwxr-x 37 maryo gnomes 3800 2003-05-12 22:29 ..
dr-xr-xr-x 2 maryo gnomes 48 2003-05-12 22:29 muchado02
drwxrwxrwx 2 maryo gnomes 48 2003-05-12 22:29 muchado03
drw-rw-rw- 2 maryo gnomes 48 2003-05-12 22:29 muchado04
d-w--w--w- 2 maryo gnomes 48 2003-05-12 22:29 muchado05
dr--r--r-- 2 maryo gnomes 48 2003-05-12 22:29 muchado06
drwsrwsrwx 2 maryo gnomes 48 2003-05-12 22:29 muchado08
---------- 1 maryo gnomes 1242 2003-05-12 22:31 mydata00.lst
--w--w--w- 1 maryo gnomes 7754 2003-05-12 22:33 mydata02.lst
-r--r--r-- 1 maryo gnomes 21017 2003-05-12 22:32 mydata04.lst
-rw-rw-rw- 1 maryo gnomes 41105 2003-05-12 22:32 mydata06.lst
&prompt;
The columns represent (from left to right) permissions, number of hard links to file, owner, group, size
(bytes), access date, time of last modification, and file name.
An overview of the permissions field is shown in Overview of UNIX permissions
field.
Any bit flag may be unset. An unset bit flag is the equivalent of "cannot" and is represented
as a - character (see )
readwriteexecuteusergroupotherExample File
-rwxr-x--- Means:
^^^ The owner (user) can read, write, execute
^^^ the group can read and execute
^^^ everyone else cannot do anything with it.
character deviceblock devicepipe deviceUNIX Domain Socket
Additional possibilities in the [type] field are c = character device, b = block device, p = pipe device,
s = UNIX Domain Socket.
readwriteexecuteSGIDSUID
The letters rwxXst set permissions for the user, group, and others as read (r), write (w),
execute (or access for directories) (x), execute only if the file is a directory or already has execute
permission for some user (X), set user (SUID) or group ID (SGID) on execution (s), sticky (t).
sticky bitunlinked/tmpworld-writable
When the sticky bit is set on a directory, files in that directory may be unlinked (deleted) or renamed only by root or their owner.
Without the sticky bit, anyone able to write to the directory can delete or rename files. The sticky bit is commonly found on
directories, such as /tmp, that are world-writable.
writereadsetting up directoriesset user idSUIDset group idSGID
When the set user or group ID bit (s) is set on a directory, then all files created within it will be owned by the user and/or
group whose `set user or group' bit is set. This can be helpful in setting up directories for which it is desired that
all users who are in a group should be able to write to and read from a file, particularly when it is undesirable for that file
to be exclusively owned by a user whose primary group is not the group that all such users belong to.
When a directory is set d-wx--x---, the owner can read and create (write) files in it, but because
the (r) read flags are not set, files cannot be listed (seen) in the directory by anyone. The group can read files in the
directory but cannot create new files. If files in the directory are set to be readable and writable for the group, then
group members will be able to write to (or delete) them.
Protecting Directories and Files from Deletionprotect filesprotect directoriesaccess controlscapability to delete
People have asked on the Samba mailing list how is it possible to protect files or directories from deletion by users.
For example, Windows NT/2K/XP provides the capacity to set access controls on a directory into which people can
write files but not delete them. It is possible to set an ACL on a Windows file that permits the file to be written to
but not deleted. Such concepts are foreign to the UNIX operating system file space. Within the UNIX file system
anyone who has the ability to create a file can write to it. Anyone who has write permission on the
directory that contains a file and has write permission for it has the capability to delete it.
directory permissionsdelete a filewrite access
For the record, in the UNIX environment the ability to delete a file is controlled by the permissions on
the directory that the file is in. In other words, a user can delete a file in a directory to which that
user has write access, even if that user does not own the file.
file system capabilitiesinheritancePOSIX ACLsextended attributes
Of necessity, Samba is subject to the file system semantics of the host operating system. Samba is therefore
limited in the file system capabilities that can be made available through Windows ACLs, and therefore performs
a "best fit" translation to POSIX ACLs. Some UNIX file systems do, however support, a feature known
as extended attributes. Only the Windows concept of inheritance is implemented by Samba through
the appropriate extended attribute.
extended attributesimmutablechattrCAP_LINUX_IMMUTABLE
The specific semantics of the extended attributes are not consistent across UNIX and UNIX-like systems such as Linux.
For example, it is possible on some implementations of the extended attributes to set a flag that prevents the directory
or file from being deleted. The extended attribute that may achieve this is called the immutable bit.
Unfortunately, the implementation of the immutable flag is NOT consistent with published documentation. For example, the
man page for the chattr on SUSE Linux 9.2 says:
A file with the i attribute cannot be modified: it cannot be deleted
or renamed, no link can be created to this file and no data can be
written to the file. Only the superuser or a process possessing the
CAP_LINUX_IMMUTABLE capability can set or clear this attribute.
A simple test can be done to check if the immutable flag is supported on files in the file system of the Samba host
server.
Test for File Immutibility Support
Create a file called filename.
Login as the root user, then set the immutibile flag on a test file as follows:
&rootprompt; chattr +i `filename'
Login as the user who owns the file (not root) and attempt to remove the file as follows:
mystic:/home/hannibal > rm filename
It will not be possible to delete the file if the immutable flag is correctly honored.
On operating systems and file system types that support the immutable bit, it is possible to create directories
that cannot be deleted. Check the man page on your particular host system to determine whether or not
immutable directories are writable. If they are not, then the entire directory and its contents will effectively
be protected from writing (file creation also) and deletion.
Share Definition Access Controlspermissionsshare
The following parameters in the &smb.conf; file sections define a share control or affect access controls.
Before using any of the following options, please refer to the man page for &smb.conf;.
User- and Group-Based Controls
User- and group-based controls can prove quite useful. In some situations it is distinctly desirable to
force all file system operations as if a single user were doing so. The use of the
and behavior will achieve this.
In other situations it may be necessary to use a paranoia level of control to ensure that only particular
authorized persons will be able to access a share or its contents. Here the use of the
or the parameter may be useful.
As always, it is highly advisable to use the easiest to maintain and the least ambiguous method for
controlling access. Remember, when you leave the scene, someone else will need to provide assistance, and
if he or she finds too great a mess or does not understand what you have done, there is risk of
Samba being removed and an alternative solution being adopted.
User and Group Based Controls enumerates these controls.
User- and Group-Based ControlsControl ParameterDescription, Action, Notes
List of users who will be granted administrative privileges on the share.
They will do all file operations as the superuser (root).
Users in this list will be able to do anything they like on the share,
irrespective of file permissions.
Specifies a UNIX group name that will be assigned as the default primary group
for all users connecting to this service.
Specifies a UNIX username that will be assigned as the default user for all users connecting to this service.
This is useful for sharing files. Incorrect use can cause security problems.
If this parameter is set for a service, then no password is required to connect to the service. Privileges will be
those of the guest account.
List of users that should not be allowed to login to this service.
Controls whether connections with usernames not in the user list will be allowed.
List of users that are given read-only access to a service. Users in this list
will not be given write access, no matter what the read-only option is set to.
Refer to the &smb.conf; man page for more information; this is a complex and potentially misused parameter.
List of users that should be allowed to login to this service.
List of users that are given read-write access to a service.
File and Directory Permissions-Based Controls
Directory permission-based controls, if misused, can result in considerable difficulty in diagnosing the causes of
misconfiguration. Use them sparingly and carefully. By gradually introducing each, one at a time, undesirable side
effects may be detected. In the event of a problem, always comment all of them out and then gradually reintroduce
them in a controlled way.
Refer to File and Directory Permission Based Controls for information
regarding the parameters that may be used to set file and directory permission-based access controls.
File and Directory Permission-Based ControlsControl ParameterDescription, Action, Notes
Refer to the &smb.conf; man page.
The octal modes used when converting DOS modes to UNIX modes when creating UNIX directories.
See also directory security mask.
Enabling this parameter allows a user who has write access to the file to modify the permissions on it.
This parameter specifies a set of UNIX-mode bit permissions that will always be set on a file created by Samba.
This parameter specifies a set of UNIX-mode bit permissions that will always be set on a directory created by Samba.
Controls UNIX permission bits modified when a Windows NT client is manipulating UNIX permissions on a directory.
Controls UNIX permission bits modified when a Windows NT client manipulates UNIX permissions.
Prevents clients from seeing the existence of files that cannot be read.
Prevents clients from seeing the existence of files that cannot be written to. Unwritable directories are shown as usual.
This parameter controls whether smbd will attempt to map UNIX permissions into Windows NT ACLs.
Controls UNIX permission bits modified when a Windows NT client is manipulating the UNIX permissions on a file.
Miscellaneous Controls
The parameters documented in Other Controls are often used by administrators
in ways that create inadvertent barriers to file access. Such are the consequences of not understanding the
full implications of &smb.conf; file settings.
Other ControlsControl ParameterDescription, Action, Notes,
,
This means that all file name lookup will be done in a case-sensitive manner.
Files will be created with the precise file name Samba received from the MS Windows client.
Client-side caching policy parallels MS Windows client-side file caching capabilities.
Allows specifying a comma-delimited list of directories that the server should always show as empty.
This option is mainly used as a compatibility option for Visual C++ when used against Samba shares.
DOS and Windows allow users to change file timestamps if they can write to the file. POSIX semantics prevent this.
This option allows DOS and Windows behavior.
Oplocks are the way that SMB clients get permission from a server to locally cache file operations. If a server grants an
oplock, the client is free to assume that it is the only one accessing the file, and it will aggressively cache file data.
,
,
Note: MS Windows Explorer allows override of files marked as hidden so they will still be visible.
If this parameter is yes, then users of a service may not create or modify files in the service's directory.
List of files and directories that are neither visible nor accessible.
Access Controls on Sharesper-share access controlEveryone - Full Controlspecific restrictionsshare accesspermissionsshare ACLs
This section deals with how to configure Samba per-share access control restrictions.
By default, Samba sets no restrictions on the share itself. Restrictions on the share itself
can be set on MS Windows NT4/200x/XP shares. This can be an effective way to limit who can
connect to a share. In the absence of specific restrictions, the default setting is to allow
the global user Everyone - Full Control (full control, change and read).
access controlMMCComputer Management
At this time Samba does not provide a tool for configuring access control settings on the share
itself. The only way to create those settings is to use either the NT4 Server Manager or the Windows 200x
Microsoft Management Console (MMC) for Computer Management. There are currently no plans to provide
this capability in the Samba command-line tool set.
share_info.tdb/usr/local/samba/vartdbdumptdb files
Samba stores the per-share access control settings in a file called share_info.tdb.
The location of this file on your system will depend on how Samba was compiled. The default location
for Samba's tdb files is under /usr/local/samba/var. If the tdbdump
utility has been compiled and installed on your system, then you can examine the contents of this file
by executing tdbdump share_info.tdb in the directory containing the tdb files.
Share Permissions Management
The best tool for share permissions management is platform-dependent. Choose the best tool for your environment.
Windows NT4 Workstation/Servermanage share permissionsshare permissionsNT Server ManagerWindows NT4
The tool you need to manage share permissions on a Samba server from a Windows NT4 Workstation or Server
is the NT Server Manager. Server Manager is shipped with Windows NT4 Server products but not with Windows
NT4 Workstation. You can obtain the NT Server Manager for MS Windows NT4 Workstation from the Microsoft
web site support section.
Instructions
Launch the NT4 Server Manager and click on the Samba server you want to
administer. From the menu select Computer, then click on
Shared Directories.
Click on the share that you wish to manage and click the Properties tab, then click
the Permissions tab. Now you can add or change access control settings as you wish.
Windows 200x/XPWindows NT4/200x/XPACLs on shareSharingPermissions
On MS Windows NT4/200x/XP systems, ACLs on the share itself are set using
tools like the MS Explorer. For example, in Windows 200x, right-click on the shared folder,
then select Sharing, then click on Permissions. The default
Windows NT4/200x permissions allow the group "Everyone" full control on the share.
Computer ManagementMMCtool
MS Windows 200x and later versions come with a tool called the Computer Management
snap-in for the MMC. This tool can be accessed via Control Panel ->
Administrative Tools -> Computer Management.
Instructions
After launching the MMC with the Computer Management snap-in, click the menu item Action
and select Connect to another computer. If you are not logged onto a domain you will be prompted
to enter a domain login user identifier and a password. This will authenticate you to the domain.
If you are already logged in with administrative privilege, this step is not offered.
If the Samba server is not shown in the Select Computer box, type in the name of the target
Samba server in the field Name:. Now click the on [+] next to
System Tools, then on the [+] next to
Shared Folders in the left panel.
Share Permissions
In the right panel, double-click on the share on which you wish to set access control permissions.
Then click the tab Share Permissions. It is now possible to add access control entities
to the shared folder. Remember to set what type of access (full control, change, read) you
wish to assign for each entry.
Be careful. If you take away all permissions from the Everyone user without removing
this user, effectively no user will be able to access the share. This is a result of what is known as
ACL precedence. Everyone with no access means that MaryK who is
part of the group Everyone will have no access even if she is given explicit full
control access.
MS Windows Access Control Lists and UNIX InteroperabilityManaging UNIX Permissions Using NT Security Dialogspermissionsfile/directory ACLs
Windows NT clients can use their native security settings dialog box to view and modify the
underlying UNIX permissions.
This ability is careful not to compromise the security of the UNIX host on which Samba is running and
still obeys all the file permission rules that a Samba administrator can set.
Samba does not attempt to go beyond POSIX ACLs, so the various finer-grained access control
options provided in Windows are actually ignored.
All access to UNIX/Linux system files via Samba is controlled by the operating system file access controls.
When trying to figure out file access problems, it is vitally important to find the identity of the Windows
user as it is presented by Samba at the point of file access. This can best be determined from the
Samba log files.
Viewing File Security on a Samba Share
From an NT4/2000/XP client, right-click on any file or directory in a Samba-mounted drive letter
or UNC path. When the menu pops up, click on the Properties entry at the bottom
of the menu. This brings up the file Properties dialog box. Click on the
Security tab and you will see three buttons: Permissions,
Auditing, and Ownership. The Auditing
button will cause either an error message "A requested privilege is not held by the client"
to appear if the user is not the NT administrator, or a dialog intended to allow an administrator
to add auditing requirements to a file if the user is logged on as the NT administrator. This dialog is
nonfunctional with a Samba share at this time, because the only useful button, the Add
button, will not currently allow a list of users to be seen.
Viewing File Ownership
Clicking on the Ownership button brings up a dialog box telling you who owns
the given file. The owner name will be displayed like this:
SERVER\user (Long name)SERVER is the NetBIOS name of the Samba server, user
is the username of the UNIX user who owns the file, and (Long name) is the
descriptive string identifying the user (normally found in the GECOS field of the UNIX password database).
Click on the Close button to remove this dialog.
If the parameter is set to false,
the file owner will be shown as the NT user Everyone.
Take Ownership
The Take Ownership button will not allow you to change the ownership of this file to
yourself (clicking it will display a dialog box complaining that the user as whom you are currently logged onto
the NT client cannot be found). The reason for this is that changing the ownership of a file is a privileged
operation in UNIX, available only to the root user. Because clicking on this button causes
NT to attempt to change the ownership of a file to the current user logged into the NT client, this will
not work with Samba at this time.
chownownershipSeclib
There is an NT chown command that will work with Samba and allow a user with administrator
privilege connected to a Samba server as root to change the ownership of files on both a local NTFS file system
or remote mounted NTFS or Samba drive. This is available as part of the Seclib NT
security library written by Jeremy Allison of the Samba Team and is downloadable from the main Samba FTP site.
Viewing File or Directory Permissions
The third button is the Permissions button. Clicking on it brings up a dialog box
that shows both the permissions and the UNIX owner of the file or directory. The owner is displayed like this:
SERVER\
user(Long name)SERVER is the NetBIOS name of the Samba server,
user is the username of the UNIX user who owns the file, and
(Long name) is the descriptive string identifying the user (normally found in the
GECOS field of the UNIX password database).
If the parameter is set to false,
the file owner will be shown as the NT user Everyone, and the permissions will be
shown as NT Full Control.
The permissions field is displayed differently for files and directories. Both are discussed next.
File Permissions
The standard UNIX user/group/world triplet and the corresponding read, write,
execute permissions triplets are mapped by Samba into a three-element NT ACL with the
r, w, and x bits mapped into the corresponding NT
permissions. The UNIX world permissions are mapped into the global NT group Everyone, followed
by the list of permissions allowed for the UNIX world. The UNIX owner and group permissions are displayed as an NT
user icon and an NT local group icon, respectively, followed by the list
of permissions allowed for the UNIX user and group.
Because many UNIX permission sets do not map into common NT names such as read,
change, or full control, usually the permissions will be prefixed
by the words Special Access in the NT display list.
But what happens if the file has no permissions allowed for a particular UNIX user group or world component?
In order to allow no permissions to be seen and modified, Samba then overloads the NT
Take Ownership ACL attribute (which has no meaning in UNIX) and reports a component with
no permissions as having the NT O bit set. This was chosen, of course, to make it look
like a zero, meaning zero permissions. More details on the decision behind this action are given below.
Directory Permissions
Directories on an NT NTFS file system have two different sets of permissions. The first set is the ACL set on the
directory itself, which is usually displayed in the first set of parentheses in the normal RW
NT style. This first set of permissions is created by Samba in exactly the same way as normal file permissions are, described
above, and is displayed in the same way.
The second set of directory permissions has no real meaning in the UNIX permissions world and represents the
inherited permissions that any file created within this directory would inherit.
Samba synthesizes these inherited permissions for NT by returning as an NT ACL the UNIX permission mode that a new file
created by Samba on this share would receive.
Modifying File or Directory Permissions
Modifying file and directory permissions is as simple as changing the displayed permissions in the dialog box
and clicking on OK. However, there are limitations that a user needs to be aware of,
and also interactions with the standard Samba permission masks and mapping of DOS attributes that also need to
be taken into account.
If the parameter is set to false, any attempt to
set security permissions will fail with an "Access Denied" message.
The first thing to note is that the Add button will not return a list of users in Samba
(it will give an error message saying "The remote procedure call failed and did not
execute"). This means that you can only manipulate the current user/group/world permissions listed
in the dialog box. This actually works quite well because these are the only permissions that UNIX actually
has.
If a permission triplet (either user, group, or world) is removed from the list of permissions in the NT
dialog box, then when the OK button is pressed, it will be applied as no
permissions on the UNIX side. If you view the permissions again, the no
permissions entry will appear as the NT O flag, as described above. This allows
you to add permissions back to a file or directory once you have removed them from a triplet component.
Because UNIX supports only the r, w, and x bits of an NT ACL, if
other NT security attributes such as Delete Access are selected, they will be ignored
when applied on the Samba server.
When setting permissions on a directory, the second set of permissions (in the second set of parentheses) is
by default applied to all files within that directory. If this is not what you want, you must uncheck the
Replace permissions on existing files checkbox in the NT dialog before clicking on
OK.
If you wish to remove all permissions from a user/group/world component, you may either highlight the
component and click on the Remove button or set the component to only have the special
Take Ownership permission (displayed as O) highlighted.
Interaction with the Standard Samba create mask ParametersThere are four parameters that control interaction with the standard Samba create mask parameters:
When a user clicks on OK to apply the
permissions, Samba maps the given permissions into a user/group/world
r/w/x triplet set, and then checks the changed permissions for a
file against the bits set in the
parameter. Any bits that
were changed that are not set to 1 in this parameter are left alone
in the file permissions.
Essentially, zero bits in the
may be treated as a set of bits the user is not
allowed to change, and one bits are those the user is allowed to change.
If not explicitly set, this parameter defaults to the same value as
the parameter. To allow a user to modify all the
user/group/world permissions on a file, set this parameter to 0777.
Next Samba checks the changed permissions for a file against the bits set in the
parameter. Any bits
that were changed that correspond to bits set to 1 in this parameter
are forced to be set.
Essentially, bits set in the force security mode parameter
may be treated as a set of bits that, when modifying security on a file, the user
has always set to be on.
If not explicitly set, this parameter defaults to the same value
as the parameter.
To allow a user to modify all the user/group/world permissions on a file
with no restrictions, set this parameter to 000. The
and force
security mode parameters are applied to the change
request in that order.
For a directory, Samba performs the same operations as
described above for a file except it uses the parameter
directory security mask instead of security
mask, and force directory security mode
parameter instead of force security mode
.
The parameter
by default is set to the same value as the directory mask
parameter and the force directory security
mode parameter by default is set to the same value as
the parameter.
In this way Samba enforces the permission restrictions that
an administrator can set on a Samba share, while still allowing users
to modify the permission bits within that restriction.
If you want to set up a share that allows users full control
in modifying the permission bits on their files and directories and
does not force any particular bits to be set on,
then set the following parameters in the &smb.conf; file in that
share-specific section:
0777007770Interaction with the Standard Samba File Attribute Mapping
Samba maps some of the DOS attribute bits (such as read-only)
into the UNIX permissions of a file. This means there can
be a conflict between the permission bits set via the security
dialog and the permission bits set by the file attribute mapping.
If a file has no UNIX read access for the owner, it will show up
as read-only in the standard file attributes tabbed dialog.
Unfortunately, this dialog is the same one that contains the security information
in another tab.
What this can mean is that if the owner changes the permissions
to allow himself or herself read access using the security dialog, clicks on
OK to get back to the standard attributes tab
dialog, and clicks on OK on that dialog, then
NT will set the file permissions back to read-only (as that is what
the attributes still say in the dialog). This means that after setting
permissions and clicking on OK to get back to the
attributes dialog, you should always press Cancel
rather than OK to ensure that your changes
are not overridden.
Windows NT/200X ACLs and POSIX ACLs Limitations
Windows administrators are familiar with simple ACL controls, and they typically
consider that UNIX user/group/other (ugo) permissions are inadequate and not
sufficiently fine-grained.
Competing SMB implementations differ in how they handle Windows ACLs. Samba handles
Windows ACLs from the perspective of UNIX file system administration and thus adopts
the limitations of POSIX ACLs. Therefore, where POSIX ACLs lack a capability of the
Windows NT/200X ACLs, the POSIX semantics and limitations are imposed on the Windows
administrator.
POSIX ACLs present an interesting challenge to the UNIX administrator and therefore
force a compromise to be applied to Windows ACLs administration. POSIX ACLs are not
covered by an official standard; rather, the latest standard is a draft standard
1003.1e revision 17. This is the POSIX document on which the Samba implementation has
been implemented.
UNIX vendors differ in the manner in which POSIX ACLs are implemented. There are a
number of Linux file systems that support ACLs. Samba has to provide a way to make
transparent all the differences between the various implementations of POSIX ACLs.
The pressure for ACLs support in Samba has noticeably increased the pressure to
standardize ACLs support in the UNIX world.
Samba has to deal with the complicated matter of handling the challenge of the Windows
ACL that implements inheritance, a concept not anticipated by POSIX
ACLs as implemented in UNIX file systems. Samba provides support for masks
that permit normal ugo and ACLs functionality to be overridden. This further complicates
the way in which Windows ACLs must be implemented.
UNIX POSIX ACL Overview
In examining POSIX ACLs we must consider the manner in which they operate for
both files and directories. File ACLs have the following significance:
# file: testfile <- the file name
# owner: jeremy <-- the file owner
# group: users <-- the POSIX group owner
user::rwx <-- perms for the file owner (user)
user:tpot:r-x <-- perms for the additional user `tpot'
group::r-- <-- perms for the file group owner (group)
group:engrs:r-- <-- perms for the additonal group `engineers'
mask:rwx <-- the mask that is `ANDed' with groups
other::--- <-- perms applied to everyone else (other)
Directory ACLs have the following signficance:
# file: testdir <-- the directory name
# owner: jeremy <-- the directory owner
# group: jeremy <-- the POSIX group owner
user::rwx <-- directory perms for owner (user)
group::rwx <-- directory perms for owning group (group)
mask::rwx <-- the mask that is `ANDed' with group perms
other:r-x <-- perms applied to everyone else (other)
default:user::rwx <-- inherited owner perms
default:user:tpot:rwx <-- inherited extra perms for user `tpot'
default:group::r-x <-- inherited group perms
default:mask:rwx <-- inherited default mask
default:other:--- <-- inherited permissions for everyone (other)
Mapping of Windows File ACLs to UNIX POSIX ACLs
Microsoft Windows NT4/200X ACLs must of necessity be mapped to POSIX ACLs.
The mappings for file permissions are shown in How
Windows File ACLs Map to UNIX POSIX File ACLs.
The # character means this flag is set only when the Windows administrator
sets the Full Control flag on the file.
How Windows File ACLs Map to UNIX POSIX File ACLsWindows ACEFile Attribute FlagFull Control#Traverse Folder/Execute FilexList Folder/Read DatarRead AttributesrRead Extended AttriburesrCreate Files/Write DatawCreate Folders/Append DatawWrite AttributeswWrite Extended AttributeswDelete Subfolders and FileswDelete#Read PermissionsallChange Permissions#Take Ownership#
As can be seen from the mapping table, there is no one-to-one mapping capability, and therefore
Samba must make a logical mapping that will permit Windows to operate more-or-less the way
that is intended by the administrator.
In general the mapping of UNIX POSIX user/group/other permissions will be mapped to
Windows ACLs. This has precedence over the creation of POSIX ACLs. POSIX ACLs are necessary
to establish access controls for users and groups other than the user and group that
own the file or directory.
The UNIX administrator can set any directory permission from within the UNIX environment.
The Windows administrator is more restricted in that it is not possible from within
Windows Explorer to remove read permission for the file owner.
Mapping of Windows Directory ACLs to UNIX POSIX ACLs
Interesting things happen in the mapping of UNIX POSIX directory permissions and
UNIX POSIX ACLs to Windows ACEs (Access Control Entries, the discrete components of
an ACL) are mapped to Windows directory ACLs.
Directory permissions function in much the same way as shown for file permissions, but
there are some notable exceptions and a few peculiarities that the astute administrator
will want to take into account in the setting up of directory permissions.
Common Errors
File, directory, and share access problems are common topics on the mailing list. The following
are examples recently taken from the mailing list.
Users Cannot Write to a Public Share
The following complaint has frequently been voiced on the Samba mailing list:
We are facing some troubles with file/directory permissions. I can log on the domain as admin user (root),
and there's a public share on which everyone needs to have permission to create/modify files, but only
root can change the file, no one else can. We need to constantly go to the server to
chgrp -R users * and chown -R nobody * to allow
other users to change the file.
Here is one way the problem can be solved:
Go to the top of the directory that is shared.
Set the ownership to whatever public user and group you want
&prompt;find `directory_name' -type d -exec chown user:group {}\;
&prompt;find `directory_name' -type d -exec chmod 2775 {}\;
&prompt;find `directory_name' -type f -exec chmod 0775 {}\;
&prompt;find `directory_name' -type f -exec chown user:group {}\;
The above will set the SGID bit on all directories. Read your
UNIX/Linux man page on what that does. This ensures that all files and directories
that are created in the directory tree will be owned by the current user and will
be owned by the group that owns the directory in which it is created.
Directory is /foodbar:
&prompt;chown jack:engr /foodbarThis is the same as doing:
&prompt;chown jack /foodbar
&prompt;chgrp engr /foodbarNow type:
&prompt;chmod 2775 /foodbar
&prompt;ls -al /foodbar/..You should see:
drwxrwsr-x 2 jack engr 48 2003-02-04 09:55 foodbar
Now type:
&prompt;su - jill
&prompt;cd /foodbar
&prompt;touch Afile
&prompt;ls -al
You should see that the file Afile created by Jill will have ownership
and permissions of Jack, as follows:
-rw-r--r-- 1 jill engr 0 2007-01-18 19:41 Afile
If the user that must have write permission in the directory is not a member of the group
engr set in the &smb.conf; entry for the share:
engrFile Operations Done as root with force user Set
When you have a user in , Samba will always do file operations for
this user as root, even if has been set.
MS Word with Samba Changes Owner of FileQuestion:When user B saves a word document that is owned by user A,
the updated file is now owned by user B. Why is Samba doing this? How do I fix this?Answer: Word does the following when you modify/change a Word document: MS Word creates a new document with
a temporary name. Word then closes the old document and deletes it, then renames the new document to the original document name.
There is no mechanism by which Samba can in any way know that the new document really should be owned by the owners
of the original file. Samba has no way of knowing that the file will be renamed by MS Word. As far as Samba is able
to tell, the file that gets created is a new file, not one that the application (Word) is updating.
There is a workaround to solve the permissions problem. It involves understanding how you can manage file
system behavior from within the &smb.conf; file, as well as understanding how UNIX file systems work. Set on the directory
in which you are changing Word documents: chmod g+s `directory_name'. This ensures that all files will
be created with the group that owns the directory. In &smb.conf; share declaration section set:
06600770
These two settings will ensure that all directories and files that get created in the share will be readable/writable by the
owner and group set on the directory itself.