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Table of Contents
Samba-3 implements a new capability to work concurrently with multiple account backends. The possible new combinations of password backends allows Samba-3 a degree of flexibility and scalability that previously could be achieved only with MS Windows Active Directory (ADS). This chapter describes the new functionality and how to get the most out of it.
The three passdb backends that are fully maintained (actively supported) by the Samba Team are:
smbpasswd
(being obsoleted), tdbsam
(a tdb-based binary file format),
and ldapsam
(LDAP directory). Of these, only the ldapsam
backend
stores both POSIX (UNIX) and Samba user and group account information in a single repository. The
smbpasswd
and tdbsam
backends store only Samba user accounts.
In a strict sense, there are three supported account storage and access systems. One of these is considered
obsolete (smbpasswd). It is recommended to use the tdbsam
method for all simple systems. Use
ldapsam
for larger and more complex networks.
In a strict and literal sense, the passdb backends are account storage mechanisms (or methods) alone. The choice of terminology can be misleading, however we are stuck with this choice of wording. This chapter documents the nature of the account storage system with a focus on user and trust accounts. Trust accounts have two forms, machine trust accounts (computer accounts) and interdomain trust accounts. These are all treated as user-like entities.
Samba-3 provides for complete backward compatibility with Samba-2.2.x functionality as follows:
This isn't really a backend at all, but is listed here for simplicity. Samba can be configured to pass
plaintext authentication requests to the traditional UNIX/Linux /etc/passwd
and
/etc/shadow
-style subsystems. On systems that have Pluggable Authentication Modules
(PAM) support, all PAM modules are supported. The behavior is just as it was with Samba-2.2.x, and the
protocol limitations imposed by MS Windows clients apply likewise. Please refer to Technical Information, for more information regarding the limitations of plaintext
password usage.
This option allows continued use of the smbpasswd
file that maintains a plain ASCII (text) layout that includes the MS Windows
LanMan and NT-encrypted passwords as well as a field that stores some
account information. This form of password backend does not store any of
the MS Windows NT/200x SAM (Security Account Manager) information required to
provide the extended controls that are needed for more comprehensive
interoperation with MS Windows NT4/200x servers.
This backend should be used only for backward compatibility with older versions of Samba. It may be deprecated in future releases.
There is a password backend option that allows continued operation with an existing OpenLDAP backend that uses the Samba-2.2.x LDAP schema extension. This option is provided primarily as a migration tool, although there is no reason to force migration at this time. This tool will eventually be deprecated.
Samba-3 introduces a number of new password backend capabilities.
This backend provides a rich database backend for local servers. This backend is not suitable for multiple domain controllers (i.e., PDC + one or more BDC) installations.
The tdbsam password backend stores the old smbpasswd information plus the extended MS Windows NT/200x SAM information into a binary format TDB (trivial database) file. The inclusion of the extended information makes it possible for Samba-3 to implement the same account and system access controls that are possible with MS Windows NT4/200x-based systems.
The inclusion of the tdbsam capability is a direct response to user requests to allow simple site operation without the overhead of the complexities of running OpenLDAP. It is recommended to use this only for sites that have fewer than 250 users. For larger sites or implementations, the use of OpenLDAP or of Active Directory integration is strongly recommended.
This provides a rich directory backend for distributed account installation.
Samba-3 has a new and extended LDAP implementation that requires configuration
of OpenLDAP with a new format Samba schema. The new format schema file is
included in the examples/LDAP
directory of the Samba distribution.
The new LDAP implementation significantly expands the control abilities that were possible with prior versions of Samba. It is now possible to specify “per-user” profile settings, home directories, account access controls, and much more. Corporate sites will see that the Samba Team has listened to their requests both for capability and greater scalability.
It is expected that the MySQL-based SAM will be very popular in some corners. This database backend will be of considerable interest to sites that want to leverage existing MySQL technology.
Makes use of a PostgreSQL database to store account information. This backend is largely undocumented at the moment, though its configuration is very similar to that of the mysqlsam backend.
Allows the account and password data to be stored in an XML format data file. This backend cannot be used for normal operation, it can only be used in conjunction with pdbedit's pdb2pdb functionality. The Document Type Definition (DTD) file that is used might be subject to changes in the future. (See the XML reference for a definition of XML terms.)
The xmlsam
option can be useful for account migration between database
backends or backups. Use of this tool allows the data to be edited before migration
into another backend format.
Old Windows clients send plaintext passwords over the wire. Samba can check these passwords by encrypting them and comparing them to the hash stored in the UNIX user database.
Newer Windows clients send encrypted passwords (LanMan and NT hashes) instead of plaintext passwords over the wire. The newest clients will send only encrypted passwords and refuse to send plaintext passwords unless their registry is tweaked.
Many people ask why Samba cannot simply use the UNIX password database. Windows requires passwords that are encrypted in its own format. The UNIX passwords can't be converted to UNIX-style encrypted passwords. Because of that, you can't use the standard UNIX user database, and you have to store the LanMan and NT hashes somewhere else.
In addition to differently encrypted passwords, Windows also stores certain data for each
user that is not stored in a UNIX user database: for example, workstations the user may logon from,
the location where the user's profile is stored, and so on. Samba retrieves and stores this
information using a passdb backend. Commonly available backends are LDAP,
tdbsam, plain text file, and MySQL. For more information, see the man page for smb.conf
regarding the
passdb backend parameter.
The resolution of SIDs to UIDs is fundamental to correct operation of Samba. In both cases shown, if winbindd is not running or cannot be contacted, then only local SID/UID resolution is possible. See resolution of SIDs to UIDs and resolution of UIDs to SIDs diagrams.
The UNIX and SMB password encryption techniques seem similar on the surface. This similarity is, however, only skin deep. The UNIX scheme typically sends clear-text passwords over the network when logging in. This is bad. The SMB encryption scheme never sends the clear-text password over the network, but it does store the 16-byte hashed values on disk. This is also bad. Why? Because the 16 byte hashed values are a “password equivalent.” You cannot derive the user's password from them, but they could potentially be used in a modified client to gain access to a server. This would require considerable technical knowledge on behalf of the attacker but is perfectly possible. You should therefore treat the data stored in whatever passdb backend you use (smbpasswd file, LDAP, MYSQL) as though it contained the clear-text passwords of all your users. Its contents must be kept secret, and the file should be protected accordingly.
Ideally, we would like a password scheme that involves neither plaintext passwords on the network nor plaintext passwords on disk. Unfortunately, this is not available because Samba is stuck with having to be compatible with other SMB systems (Windows NT, Windows for Workgroups, Windows 9x/Me).
Windows NT 4.0 Service Pack 3 changed the default setting so plaintext passwords are disabled from being sent over the wire. This mandates either the use of encrypted password support or editing the Windows NT registry to re-enable plaintext passwords.
The following versions of Microsoft Windows do not support full domain security protocols, although they may log onto a domain environment:
MS DOS Network client 3.0 with the basic network redirector installed.
Windows 95 with the network redirector update installed.
Windows 98 [Second Edition].
Windows Me.
MS Windows XP Home does not have facilities to become a domain member, and it cannot participate in domain logons.
The following versions of MS Windows fully support domain security protocols.
Windows NT 3.5x.
Windows NT 4.0.
Windows 2000 Professional.
Windows 200x Server/Advanced Server.
Windows XP Professional.
All current releases of Microsoft SMB/CIFS clients support authentication via the SMB challenge/response mechanism described here. Enabling clear-text authentication does not disable the ability of the client to participate in encrypted authentication. Instead, it allows the client to negotiate either plaintext or encrypted password handling.
MS Windows clients will cache the encrypted password alone. Where plaintext passwords are re-enabled through the appropriate registry change, the plaintext password is never cached. This means that in the event that a network connections should become disconnected (broken), only the cached (encrypted) password will be sent to the resource server to effect an auto-reconnect. If the resource server does not support encrypted passwords, the auto-reconnect will fail. Use of encrypted passwords is strongly advised.
Plaintext passwords are not passed across the network. Someone using a network sniffer cannot just record passwords going to the SMB server.
Plaintext passwords are not stored anywhere in memory or on disk.
Windows NT does not like talking to a server that does not support encrypted passwords. It will refuse to browse the server if the server is also in user-level security mode. It will insist on prompting the user for the password on each connection, which is very annoying. The only thing you can do to stop this is to use SMB encryption.
Encrypted password support allows automatic share (resource) reconnects.
Plaintext passwords are not kept on disk and are not cached in memory.
Plaintext passwords use the same password file as other UNIX services, such as Login and FTP.
Use of other services (such as Telnet and FTP) that send plaintext passwords over the network makes sending them for SMB not such a big deal.
Every operation in UNIX/Linux requires a user identifier (UID), just as in MS Windows NT4/200x this requires a security identifier (SID). Samba provides two means for mapping an MS Windows user to a UNIX/Linux UID.
First, all Samba SAM database accounts require a UNIX/Linux UID that the account will map to. As users are added to the account information database, Samba will call the add user script interface to add the account to the Samba host OS. In essence all accounts in the local SAM require a local user account.
The second way to map Windows SID to UNIX UID is via the idmap uid and
idmap gid parameters in smb.conf
. Please refer to the man page for information about
these parameters. These parameters are essential when mapping users from a remote (non-member Windows client
or a member of a foreign domain) SAM server.
Samba-3 has a special facility that makes it possible to maintain identical UIDs and GIDs on all servers in a distributed network. A distributed network is one where there exists a PDC, one or more BDCs, and/or one or more domain member servers. Why is this important? This is important if files are being shared over more than one protocol (e.g., NFS) and where users are copying files across UNIX/Linux systems using tools such as rsync.
The special facility is enabled using a parameter called idmap backend
.
The default setting for this parameter is an empty string. Technically it is possible to use
an LDAP-based idmap backend for UIDs and GIDs, but it makes most sense when this is done for
network configurations that also use LDAP for the SAM backend.
Example Configuration with the LDAP idmap Backend
shows that configuration.
Example 10.1. Example Configuration with the LDAP idmap Backend
[global] |
idmap backend = ldap:ldap://ldap-server.quenya.org:636 |
# Alternatively, this could be specified as: |
idmap backend = ldap:ldaps://ldap-server.quenya.org |
A network administrator who wants to make significant use of LDAP backends will sooner or later be exposed to the excellent work done by PADL Software. PADL http://www.padl.com have produced and released to open source an array of tools that might be of interest. These tools include:
nss_ldap: An LDAP name service switch (NSS) module to provide native name service support for AIX, Linux, Solaris, and other operating systems. This tool can be used for centralized storage and retrieval of UIDs and GIDs.
pam_ldap: A PAM module that provides LDAP integration for UNIX/Linux system access authentication.
idmap_ad: An IDMAP backend that supports the Microsoft Services for UNIX RFC 2307 schema available from the PADL Web site.
There is much excitement and interest in LDAP directories in the information technology world today. The LDAP architecture was designed to be highly scalable. It was also designed for use across a huge number of potential areas of application encompassing a wide range of operating systems and platforms. LDAP technologies are at the heart of the current generations of Federated Identity Management (FIM) solutions that can underlie a corporate Single Sign-On (SSO) environment.
LDAP implementations have been built across a wide variety of platforms. It lies at the core of Microsoft Windows Active Directory services (ADS), Novell's eDirectory, as well as many others. Implementation of the directory services LDAP involves interaction with legacy as well as new generation applications, all of which depend on some form of authentication services.
UNIX services can utilize LDAP directory information for authentication and access controls through intermediate tools and utilities. The total environment that consists of the LDAP directory and the middle-ware tools and utilities makes it possible for all user access to the UNIX platform to be managed from a central environment and yet distributed to wherever the point of need may be physically located. Applications that benefit from this infrastructure include: UNIX login shells, mail and messaging systems, quota controls, printing systems, DNS servers, DHCP servers, and also Samba.
Many sites are installing LDAP for the first time in order to provide a scalable passdb backend for Samba. Others are faced with the need to adapt an existing LDAP directory to new uses such as for the Samba SAM backend. Whatever your particular need and attraction to Samba may be, decisions made in respect of the design of the LDAP directory structure and its implementation are of a durable nature for the site. These have far-reaching implications that affect long-term information systems management costs.
Do not rush into an LDAP deployment. Take the time to understand how the design of the Directory Information Tree (DIT) may impact current and future site needs, as well as the ability to meet them. The way that Samba SAM information should be stored within the DIT varies from site to site and with each implementation new experience is gained. It is well understood by LDAP veterans that first implementations create awakening, second implementations of LDAP create fear, and third-generation deployments bring peace and tranquility.
Samba requires UNIX POSIX identity information as well as a place to store information that is specific to Samba and the Windows networking environment. The most used information that must be dealt with includes: user accounts, group accounts, machine trust accounts, interdomain trust accounts, and intermediate information specific to Samba internals.
The example deployment guidelines in this book, as well as other books and HOWTO documents available from the internet may not fit with established directory designs and implementations. The existing DIT may not be able to accommodate the simple information layout proposed in common sources. Additionally, you may find that the common scripts and tools that are used to provision the LDAP directory for use with Samba may not suit your needs.
It is not uncommon, for sites that have existing LDAP DITs to find necessity to generate a set of site-specific scripts and utilities to make it possible to deploy Samba within the scope of site operations. The way that user and group accounts are distributed throughout the DIT may make this a challenging matter. The solution will, of course, be rewarding, but the journey to it may be challenging. Take time to understand site needs and do not rush into deployment.
Above all, do not blindly use scripts and tools that are not suitable for your site. Check and validate all scripts before you execute them to make sure that the existing infrastructure will not be damaged by inadvertent use of an inappropriate tool.
Samba doesn't provide a turnkey solution to LDAP. It is best to deal with the design and configuration of an LDAP directory prior to integration with Samba. A working knowledge of LDAP makes Samba integration easy, and the lack of a working knowledge of LDAP can make it a frustrating experience.
Computer (machine) accounts can be placed wherever you like in an LDAP directory subject to some constraints that are described in this chapter.
The POSIX and sambaSamAccount components of computer (machine) accounts are both used by Samba. Thus, machine accounts are treated inside Samba in the same way that Windows NT4/200X treats them. A user account and a machine account are indistinquishable from each other, except that the machine account ends in a $ character, as do trust accounts.
The need for Windows user, group, machine, trust, and other accounts to be tied to a valid UNIX UID is a design decision that was made a long way back in the history of Samba development. It is unlikely that this decision will be reversed or changed during the remaining life of the Samba-3.x series.
The resolution of a UID from the Windows SID is achieved within Samba through a mechanism that must refer back to the host operating system on which Samba is running. The NSS is the preferred mechanism that shields applications (like Samba) from the need to know everything about every host OS it runs on.
Samba asks the host OS to provide a UID via the “passwd”, “shadow”, and “group” facilities in the NSS control (configuration) file. The best tool for achieving this is left up to the UNIX administrator to determine. It is not imposed by Samba. Samba provides winbindd with its support libraries as one method. It is possible to do this via LDAP, and for that Samba provides the appropriate hooks so that all account entities can be located in an LDAP directory.
For many the weapon of choice is to use the PADL nss_ldap utility. This utility must be configured so that computer accounts can be resolved to a POSIX/UNIX account UID. That is fundamentally an LDAP design question. The information provided on the Samba list and in the documentation is directed at providing working examples only. The design of an LDAP directory is a complex subject that is beyond the scope of this documentation.
Samba provides two tools for management of user and machine accounts: smbpasswd and pdbedit.
The pdbedit can be used to manage account policies in addition to Samba user account information. The policy management capability is used to administer domain default settings for password aging and management controls to handle failed login attempts.
Some people are confused when reference is made to smbpasswd
because the
name refers to a storage mechanism for SambaSAMAccount information, but it is also the name
of a utility tool. That tool is destined to eventually be replaced by new functionality that
is being added to the net toolset (see the Net Command.
The smbpasswd utility is similar to the passwd
and yppasswd programs. It maintains the two 32 byte password
fields in the passdb backend. This utility operates independently of the actual
account and password storage methods used (as specified by the passdb
backend
in the smb.conf
file.
smbpasswd works in a client-server mode where it contacts the local smbd to change the user's password on its behalf. This has enormous benefits.
smbpasswd has the capability to change passwords on Windows NT servers (this only works when the request is sent to the NT PDC if changing an NT domain user's password).
add user or machine accounts.
delete user or machine accounts.
enable user or machine accounts.
disable user or machine accounts.
set to NULL user passwords.
manage interdomain trust accounts.
To run smbpasswd as a normal user, just type:
$
smbpasswd
Old SMB password:
secret
For secret
, type the old value here or press return if
there is no old password.
New SMB Password:
new secret
Repeat New SMB Password:
new secret
If the old value does not match the current value stored for that user, or the two new values do not match each other, then the password will not be changed.
When invoked by an ordinary user, the command will allow only the user to change his or her own SMB password.
When run by root, smbpasswd may take an optional argument specifying the username whose SMB password you wish to change. When run as root, smbpasswd does not prompt for or check the old password value, thus allowing root to set passwords for users who have forgotten their passwords.
smbpasswd is designed to work in the way familiar to UNIX users who use the passwd or yppasswd commands. While designed for administrative use, this tool provides essential user-level password change capabilities.
For more details on using smbpasswd, refer to the man page (the definitive reference).
pdbedit is a tool that can be used only by root. It is used to manage the passdb backend, as well as domain-wide account policy settings. pdbedit can be used to:
add, remove, or modify user accounts.
list user accounts.
migrate user accounts.
migrate group accounts.
manage account policies.
manage domain access policy settings.
Under the terms of the Sarbanes-Oxley Act of 2002, American businesses and organizations are mandated to
implement a series of internal controls
and procedures to communicate, store,
and protect financial data. The Sarbanes-Oxley Act has far reaching implications in respect of:
Who has access to information systems that store financial data.
How personal and finacial information is treated among employees and business partners.
How security vulnerabilities are managed.
Security and patch level maintenance for all information systems.
How information systems changes are documented and tracked.
How information access controls are implemented and managed.
Auditability of all information systems in respect of change and security.
Disciplinary procedures and controls to ensure privacy.
In short, the Sarbanes-Oxley Act of 2002 is an instrument that enforces accountability in respect of business related information systems so as to ensure the compliance of all information systems that are used to store personal information and particularly for financial records processing. Similar accountabilities are being demanded around the world.
The need to be familiar with the Samba tools and facilities that permit information systems operation in compliance with government laws and regulations is clear to all. The pdbedit is currently the only Samba tool that provides the capacity to manage account and systems access controls and policies. During the remaining life-cycle of the Samba-3 series it is possible the new tools may be implemented to aid in this important area.
Domain global policy controls available in Windows NT4 compared with Samba is shown in NT4 Domain v's Samba Policy Controls.
Table 10.1. NT4 Domain v's Samba Policy Controls
NT4 policy Name | Samba Policy Name | NT4 Range | Samba Range | Samba Default |
---|---|---|---|---|
Maximum Password Age | maximum password age | 0 - 999 (days) | 0 - 4294967295 (sec) | 4294967295 |
Minimum Password Age | minimum password age | 0 - 999 (days) | 0 - 4294967295 (sec) | 0 |
Mimimum Password Length | min password length | 1 - 14 (Chars) | 0 - 4294967295 (Chars) | 5 |
Password Uniqueness | password history | 0 - 23 (#) | 0 - 4294967295 (#) | 0 |
Account Lockout - Reset count after | reset count minutes | 1 - 99998 (min) | 0 - 4294967295 (min) | 30 |
Lockout after bad logon attempts | bad lockout attempt | 0 - 998 (#) | 0 - 4294967295 (#) | 0 |
*** Not Known *** | disconnect time | TBA | 0 - 4294967295 | 0 |
Lockout Duration | lockout duration | 1 - 99998 (min) | 0 - 4294967295 (min) | 30 |
Users must log on in order to change password | user must logon to change password | 0/1 | 0 - 4294967295 | 0 |
*** Registry Setting *** | refuse machine password change | 0/1 | 0 - 4294967295 | 0 |
The pdbedit tool is the only one that can manage the account security and policy settings. It is capable of all operations that smbpasswd can do as well as a superset of them.
One particularly important purpose of the pdbedit is to allow the migration of account information from one passdb backend to another. See the XML password backend section of this chapter.
The pdbedit tool, like the smbpasswd tool, requires
that a POSIX user account already exists in the UNIX/Linux system accounts database (backend).
Neither tool will call out to the operating system to create a user account because this is
considered to be the responsibility of the system administrator. When the Windows NT4 domain
user manager is used to add an account, Samba will implement the add user script
(as well as the other interface scripts) to ensure that user, group and machine accounts are
correctly created and changed. The use of the pdbedit tool does not
make use of these interface scripts.
Before attempting to use the pdbedit tool to manage user and machine accounts, make certain that a system (POSIX) account has already been created.
The following is an example of the user account information that is stored in a tdbsam password backend. This listing was produced by running:
$
pdbedit -Lv met
UNIX username: met NT username: met Account Flags: [U ] User SID: S-1-5-21-1449123459-1407424037-3116680435-2004 Primary Group SID: S-1-5-21-1449123459-1407424037-3116680435-1201 Full Name: Melissa E Terpstra Home Directory: \\frodo\met\Win9Profile HomeDir Drive: H: Logon Script: scripts\logon.bat Profile Path: \\frodo\Profiles\met Domain: MIDEARTH Account desc: Workstations: melbelle Munged dial: Logon time: 0 Logoff time: Mon, 18 Jan 2038 20:14:07 GMT Kickoff time: Mon, 18 Jan 2038 20:14:07 GMT Password last set: Sat, 14 Dec 2002 14:37:03 GMT Password can change: Sat, 14 Dec 2002 14:37:03 GMT Password must change: Mon, 18 Jan 2038 20:14:07 GMT
Accounts can also be listed in the older smbpasswd
format:
root#
pdbedit -Lw
root:0:84B0D8E14D158FF8417EAF50CFAC29C3: AF6DD3FD4E2EA8BDE1695A3F05EFBF52:[U ]:LCT-42681AB8: jht:1000:6BBC4159020A52741486235A2333E4D2: CC099521AD554A3C3CF2556274DBCFBC:[U ]:LCT-40D75B5B: rcg:1002:E95D4331A6F23AF8AAD3B435B51404EE: BB0F2C39B04CA6100F0E535DF8314B43:[U ]:LCT-40D7C5A3: afw:1003:1AAFA7F9F6DC1DEAAAD3B435B51404EE: CE92C2F9471594CDC4E7860CA6BC62DB:[T ]:LCT-40DA501F: met:1004:A2848CB7E076B435AAD3B435B51404EE: F25F5D3405085C555236B80B7B22C0D2:[U ]:LCT-4244FAB8: aurora$:1005:060DE593EA638B8ACC4A19F14D2FF2BB: 060DE593EA638B8ACC4A19F14D2FF2BB:[W ]:LCT-4173E5CC: temptation$:1006:XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX: A96703C014E404E33D4049F706C45EE9:[W ]:LCT-42BF0C57: vaioboss$:1001:XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX: 88A30A095160072784C88F811E89F98A:[W ]:LCT-41C3878D: frodo$:1008:15891DC6B843ECA41249940C814E316B: B68EADCCD18E17503D3DAD3E6B0B9A75:[W ]:LCT-42B7979F: marvel$:1011:BF709959C3C94E0B3958B7B84A3BB6F3: C610EFE9A385A3E8AA46ADFD576E6881:[W ]:LCT-40F07A4
The pdbedit can be used to add a user account to a standalone server
or to a domain. In the example shown here the account for the user vlaan
has been created before attempting to add the SambaSAMAccount.
root#
pdbedit -a vlaan
new password: secretpw
retype new password: secretpw
Unix username: vlaan
NT username: vlaan
Account Flags: [U ]
User SID: S-1-5-21-726309263-4128913605-1168186429-3014
Primary Group SID: S-1-5-21-726309263-4128913605-1168186429-513
Full Name: Victor Laan
Home Directory: \\frodo\vlaan
HomeDir Drive: H:
Logon Script: scripts\logon.bat
Profile Path: \\frodo\profiles\vlaan
Domain: MIDEARTH
Account desc: Guest User
Workstations:
Munged dial:
Logon time: 0
Logoff time: Mon, 18 Jan 2038 20:14:07 GMT
Kickoff time: Mon, 18 Jan 2038 20:14:07 GMT
Password last set: Wed, 29 Jun 2005 19:35:12 GMT
Password can change: Wed, 29 Jun 2005 19:35:12 GMT
Password must change: Mon, 18 Jan 2038 20:14:07 GMT
Last bad password : 0
Bad password count : 0
Logon hours : FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF
An account can be deleted from the SambaSAMAccount database
root#
pdbedit -x vlaan
The account is removed without further screen output. The account is removed only from the SambaSAMAccount (passdb backend) database, it is not removed from the UNIX account backend.
The use of the NT4 domain user manager to delete an account will trigger the delete user
script
, but not the pdbedit tool.
Refer to the pdbedit man page for a full synopsis of all operations that are available with this tool.
An example of a simple change in the user account information is the change of the full name information shown here:
root#
pdbedit -r --fullname="Victor Aluicious Laan" vlaan
...
Primary Group SID: S-1-5-21-726309263-4128913605-1168186429-513
Full Name: Victor Aluicious Laan
Home Directory: \\frodo\vlaan
...
Let us assume for a moment that a user's password has expired and the user is unable to change the password at this time. It may be necessary to give the user additional grace time so that it is possible to continue to work with the account and the original password. This demonstrates how the password expiration settings may be updated
root#
pdbedit -Lv vlaan
...
Password last set: Sun, 09 Sep 2001 22:21:40 GMT
Password can change: Thu, 03 Jan 2002 15:08:35 GMT
Password must change: Thu, 03 Jan 2002 15:08:35 GMT
Last bad password : Thu, 03 Jan 2002 15:08:35 GMT
Bad password count : 2
...
The user has recorded 2 bad logon attempts and the next will lock the account, but the password is also expired. Here is how this account can be reset:
root#
pdbedit -z vlaan
...
Password last set: Sun, 09 Sep 2001 22:21:40 GMT
Password can change: Thu, 03 Jan 2002 15:08:35 GMT
Password must change: Thu, 03 Jan 2002 15:08:35 GMT
Last bad password : 0
Bad password count : 0
...
The Password must change:
parameter can be reset like this:
root#
pdbedit --pwd-must-change-time=1200000000 vlaan
...
Password last set: Sun, 09 Sep 2001 22:21:40 GMT
Password can change: Thu, 03 Jan 2002 15:08:35 GMT
Password must change: Thu, 10 Jan 2008 14:20:00 GMT
...
Another way to use this tools is to set the date like this:
root#
pdbedit --pwd-must-change-time="2010-01-01" \
--time-format="%Y-%m-%d" vlaan
...
Password last set: Sun, 09 Sep 2001 22:21:40 GMT
Password can change: Thu, 03 Jan 2002 15:08:35 GMT
Password must change: Fri, 01 Jan 2010 00:00:00 GMT
...
Refer to the strptime man page for specific time format information.
Please refer to the pdbedit man page for further information relating to SambaSAMAccount management.
To view the domain account access policies that may be configured execute:
root#
pdbedit -P ?
No account policy by that name
Account policy names are :
min password length
password history
user must logon to change password
maximum password age
minimum password age
lockout duration
reset count minutes
bad lockout attempt
disconnect time
refuse machine password change
Commands will be executed to establish controls for our domain as follows:
min password length = 8 characters.
password history = last 4 passwords.
maximum password age = 90 days.
minimum password age = 7 days.
bad lockout attempt = 8 bad logon attempts.
lockout duration = forever, account must be manually reenabled.
The following command execution will achieve these settings:
root#
pdbedit -P "min password length" -C 8 account policy value for min password length was 5 account policy value for min password length is now 8root#
pdbedit -P "password history" -C 4 account policy value for password history was 0 account policy value for password history is now 4root#
pdbedit -P "maximum password age" -C 90 account policy value for maximum password age was 4294967295 account policy value for maximum password age is now 90root#
pdbedit -P "minimum password age" -C 7 account policy value for minimum password age was 0 account policy value for minimum password age is now 7root#
pdbedit -P "bad lockout attempt" -C 8 account policy value for bad lockout attempt was 0 account policy value for bad lockout attempt is now 8root#
pdbedit -P "lockout duration" -C -1 account policy value for lockout duration was 30 account policy value for lockout duration is now 4294967295
To set the maximum (infinite) lockout time use the value of -1.
Account policies must be set individually on each PDC and BDC. At this time (Samba 3.0.11 to Samba 3.0.14a) account policies are not replicated automatically. This may be fixed before Samba 3.0.20 ships or some time there after.
Samba offers the greatest flexibility in backend account database design of any SMB/CIFS server technology available today. The flexibility is immediately obvious as one begins to explore this capability.
It is possible to specify not only multiple password backends, but even multiple
backends of the same type. For example, to use two different tdbsam
databases:
passdb backend = tdbsam:/etc/samba/passdb.tdb tdbsam:/etc/samba/old-passdb.tdb |
What is possible is not always sensible. Be careful to avoid complexity to the point that it may be said that the solution is “too clever by half!”
Older versions of Samba retrieved user information from the UNIX user database
and eventually some other fields from the file /etc/samba/smbpasswd
or /etc/smbpasswd
. When password encryption is disabled, no
SMB-specific data is stored at all. Instead, all operations are conducted via the way
that the Samba host OS will access its /etc/passwd
database.
On most Linux systems, for example, all user and group resolution is done via PAM.
Traditionally, when configuring encrypt passwords = yes
in Samba's smb.conf
file, user account information such as username, LM/NT password hashes,
password change times, and account flags have been stored in the smbpasswd(5)
file. There are several disadvantages to this approach for sites with large numbers of users
(counted in the thousands).
The first problem is that all lookups must be performed sequentially. Given that there are approximately two lookups per domain logon (one during intial logon validation and one for a session connection setup, such as when mapping a network drive or printer), this is a performance bottleneck for large sites. What is needed is an indexed approach such as that used in databases.
The second problem is that administrators who desire to replicate an smbpasswd file to more than one Samba server are left to use external tools such as rsync(1) and ssh(1) and write custom, in-house scripts.
Finally, the amount of information that is stored in an smbpasswd entry leaves no room for additional attributes such as a home directory, password expiration time, or even a relative identifier (RID).
As a result of these deficiencies, a more robust means of storing user attributes used by smbd was developed. The API that defines access to user accounts is commonly referred to as the samdb interface (previously, this was called the passdb API and is still so named in the Samba source code trees).
Samba provides an enhanced set of passdb backends that overcome the deficiencies of the smbpasswd plaintext database. These are tdbsam, ldapsam, and xmlsam. Of these, ldapsam will be of most interest to large corporate or enterprise sites.
Samba can store user and machine account data in a “TDB” (trivial database). Using this backend does not require any additional configuration. This backend is recommended for new installations that do not require LDAP.
As a general guide, the Samba Team does not recommend using the tdbsam backend for sites that have 250 or more users. Additionally, tdbsam is not capable of scaling for use in sites that require PDB/BDC implementations that require replication of the account database. Clearly, for reason of scalability, the use of ldapsam should be encouraged.
The recommendation of a 250-user limit is purely based on the notion that this would generally involve a site that has routed networks, possibly spread across more than one physical location. The Samba Team has not at this time established the performance-based scalability limits of the tdbsam architecture.
There are sites that have thousands of users and yet require only one server.
One site recently reported having 4,500 user accounts on one UNIX system and
reported excellent performance with the tdbsam
passdb backend.
The limitation of where the tdbsam
passdb backend can be used
is not one pertaining to a limitation in the TDB storage system, it is based
only on the need for a reliable distribution mechanism for the SambaSAMAccount
backend.
There are a few points to stress that the ldapsam does not provide. The LDAP support referred to in this documentation does not include:
A means of retrieving user account information from a Windows 200x Active Directory server.
A means of replacing /etc/passwd.
The second item can be accomplished by using LDAP NSS and PAM modules. LGPL versions of these libraries can be obtained from PADL Software. More information about the configuration of these packages may be found in LDAP, System Administration by Gerald Carter, Chapter 6, Replacing NIS".
This document describes how to use an LDAP directory for storing Samba user account information traditionally stored in the smbpasswd(5) file. It is assumed that the reader already has a basic understanding of LDAP concepts and has a working directory server already installed. For more information on LDAP architectures and directories, please refer to the following sites:
Two additional Samba resources that may prove to be helpful are:
The Samba-PDC-LDAP-HOWTO maintained by Ignacio Coupeau.
The NT migration scripts from IDEALX that are geared to manage users and groups in such a Samba-LDAP domain controller configuration. Idealx also produced the smbldap-tools and the Interactive Console Management tool.
The LDAP ldapsam code was developed and tested using the OpenLDAP 2.x server and client libraries. The same code should work with Netscape's Directory Server and client SDK. However, there are bound to be compile errors and bugs. These should not be hard to fix. Please submit fixes via the process outlined in Reporting Bugs.
Samba is capable of working with any standards-compliant LDAP server.
Samba-3.0 includes the necessary schema file for OpenLDAP 2.x in the
examples/LDAP/samba.schema
directory of the source code distribution
tarball. The schema entry for the sambaSamAccount ObjectClass is shown here:
ObjectClass (1.3.6.1.4.1.7165.2.2.6 NAME 'sambaSamAccount' SUP top AUXILIARY DESC 'Samba-3.0 Auxiliary SAM Account' MUST ( uid $ sambaSID ) MAY ( cn $ sambaLMPassword $ sambaNTPassword $ sambaPwdLastSet $ sambaLogonTime $ sambaLogoffTime $ sambaKickoffTime $ sambaPwdCanChange $ sambaPwdMustChange $ sambaAcctFlags $ displayName $ sambaHomePath $ sambaHomeDrive $ sambaLogonScript $ sambaProfilePath $ description $ sambaUserWorkstations $ sambaPrimaryGroupSID $ sambaDomainName ))
The samba.schema
file has been formatted for OpenLDAP 2.0/2.1.
The Samba Team owns the OID space used by the above schema and recommends its use.
If you translate the schema to be used with Netscape DS, please submit the modified
schema file as a patch to jerry@samba.org.
Just as the smbpasswd file is meant to store information that provides information
additional to a user's /etc/passwd
entry, so is the sambaSamAccount
object meant to supplement the UNIX user account information. A sambaSamAccount is an
AUXILIARY
ObjectClass, so it can be used to augment existing
user account information in the LDAP directory, thus providing information needed
for Samba account handling. However, there are several fields (e.g., uid) that overlap
with the posixAccount ObjectClass outlined in RFC 2307. This is by design.
In order to store all user account information (UNIX and Samba) in the directory, it is necessary to use the sambaSamAccount and posixAccount ObjectClasses in combination. However, smbd will still obtain the user's UNIX account information via the standard C library calls, such as getpwnam(). This means that the Samba server must also have the LDAP NSS library installed and functioning correctly. This division of information makes it possible to store all Samba account information in LDAP, but still maintain UNIX account information in NIS while the network is transitioning to a full LDAP infrastructure.
To include support for the sambaSamAccount object in an OpenLDAP directory
server, first copy the samba.schema file to slapd's configuration directory.
The samba.schema file can be found in the directory examples/LDAP
in the Samba source distribution.
root#
cp samba.schema /etc/openldap/schema/
Next, include the samba.schema
file in slapd.conf
.
The sambaSamAccount object contains two attributes that depend on other schema
files. The uid
attribute is defined in cosine.schema
and
the displayName
attribute is defined in the inetorgperson.schema
file. Both of these must be included before the samba.schema
file.
## /etc/openldap/slapd.conf ## schema files (core.schema is required by default) include /etc/openldap/schema/core.schema ## needed for sambaSamAccount include /etc/openldap/schema/cosine.schema include /etc/openldap/schema/inetorgperson.schema include /etc/openldap/schema/nis.schema include /etc/openldap/schema/samba.schema ....
It is recommended that you maintain some indices on some of the most useful attributes, as in the following example, to speed up searches made on sambaSamAccount ObjectClasses (and possibly posixAccount and posixGroup as well):
# Indices to maintain ## required by OpenLDAP index objectclass eq index cn pres,sub,eq index sn pres,sub,eq ## required to support pdb_getsampwnam index uid pres,sub,eq ## required to support pdb_getsambapwrid() index displayName pres,sub,eq ## uncomment these if you are storing posixAccount and ## posixGroup entries in the directory as well ##index uidNumber eq ##index gidNumber eq ##index memberUid eq index sambaSID eq index sambaPrimaryGroupSID eq index sambaDomainName eq index default sub
Create the new index by executing:
root#
./sbin/slapindex -f slapd.conf
Remember to restart slapd after making these changes:
root#
/etc/init.d/slapd restart
Before you can add accounts to the LDAP database, you must create the account containers that they will be stored in. The following LDIF file should be modified to match your needs (DNS entries, and so on):
# Organization for Samba Base dn: dc=quenya,dc=org objectclass: dcObject objectclass: organization dc: quenya o: Quenya Org Network description: The Samba-3 Network LDAP Example # Organizational Role for Directory Management dn: cn=Manager,dc=quenya,dc=org objectclass: organizationalRole cn: Manager description: Directory Manager # Setting up container for Users OU dn: ou=People,dc=quenya,dc=org objectclass: top objectclass: organizationalUnit ou: People # Setting up admin handle for People OU dn: cn=admin,ou=People,dc=quenya,dc=org cn: admin objectclass: top objectclass: organizationalRole objectclass: simpleSecurityObject userPassword: {SSHA}c3ZM9tBaBo9autm1dL3waDS21+JSfQVz # Setting up container for groups dn: ou=Groups,dc=quenya,dc=org objectclass: top objectclass: organizationalUnit ou: Groups # Setting up admin handle for Groups OU dn: cn=admin,ou=Groups,dc=quenya,dc=org cn: admin objectclass: top objectclass: organizationalRole objectclass: simpleSecurityObject userPassword: {SSHA}c3ZM9tBaBo9autm1dL3waDS21+JSfQVz # Setting up container for computers dn: ou=Computers,dc=quenya,dc=org objectclass: top objectclass: organizationalUnit ou: Computers # Setting up admin handle for Computers OU dn: cn=admin,ou=Computers,dc=quenya,dc=org cn: admin objectclass: top objectclass: organizationalRole objectclass: simpleSecurityObject userPassword: {SSHA}c3ZM9tBaBo9autm1dL3waDS21+JSfQVz
The userPassword shown above should be generated using slappasswd.
The following command will then load the contents of the LDIF file into the LDAP database.
$
slapadd -v -l initldap.dif
Do not forget to secure your LDAP server with an adequate access control list as well as an admin password.
The following parameters are available in smb.conf
only if your version of Samba was built with
LDAP support. Samba automatically builds with LDAP support if the LDAP libraries are found. The
best method to verify that Samba was built with LDAP support is:
root#
smbd -b | grep LDAP
HAVE_LDAP_H
HAVE_LDAP
HAVE_LDAP_DOMAIN2HOSTLIST
HAVE_LDAP_INIT
HAVE_LDAP_INITIALIZE
HAVE_LDAP_SET_REBIND_PROC
HAVE_LIBLDAP
LDAP_SET_REBIND_PROC_ARGS
If the build of the smbd command you are using does not produce output
that includes HAVE_LDAP_H
it is necessary to discover why the LDAP headers
and libraries were not found during compilation.
LDAP-related smb.conf options include these:
These are described in the smb.conf
man page and so are not repeated here. However, an example
for use with an LDAP directory is shown in the Configuration with LDAP.
Example 10.2. Configuration with LDAP
Because user accounts are managed through the sambaSamAccount ObjectClass, you should modify your existing administration tools to deal with sambaSamAccount attributes.
Machine accounts are managed with the sambaSamAccount ObjectClass, just
like user accounts. However, it is up to you to store those accounts
in a different tree of your LDAP namespace. You should use
“ou=Groups,dc=quenya,dc=org” to store groups and
“ou=People,dc=quenya,dc=org” to store users. Just configure your
NSS and PAM accordingly (usually, in the /etc/openldap/sldap.conf
configuration file).
In Samba-3, the group management system is based on POSIX
groups. This means that Samba makes use of the posixGroup ObjectClass.
For now, there is no NT-like group system management (global and local
groups). Samba-3 knows only about Domain Groups
and, unlike MS Windows 2000 and Active Directory, Samba-3 does not
support nested groups.
There are two important points to remember when discussing the security of sambaSAMAccount entries in the directory.
These password hashes are clear-text equivalents and can be used to impersonate the user without deriving the original clear-text strings. For more information on the details of LM/NT password hashes, refer to the Account Information Database section.
To remedy the first security issue, the ldap ssl smb.conf
parameter defaults to require an encrypted session (ldap ssl = on) using the default port of 636
when
contacting the directory server. When using an OpenLDAP server, it
is possible to use the StartTLS LDAP extended operation in the place of LDAPS.
In either case, you are strongly encouraged to use secure communications protocols
(so do not set ldap ssl = off).
Note that the LDAPS protocol is deprecated in favor of the LDAPv3 StartTLS extended operation. However, the OpenLDAP library still provides support for the older method of securing communication between clients and servers.
The second security precaution is to prevent non-administrative users from
harvesting password hashes from the directory. This can be done using the
following ACL in slapd.conf
:
## allow the "ldap admin dn" access, but deny everyone else access to attrs=SambaLMPassword,SambaNTPassword by dn="cn=Samba Admin,ou=People,dc=quenya,dc=org" write by * none
The sambaSamAccount ObjectClass is composed of the attributes shown in next tables: Part A, and Part B.
Table 10.2. Attributes in the sambaSamAccount ObjectClass (LDAP), Part A
Table 10.3. Attributes in the sambaSamAccount ObjectClass (LDAP), Part B
sambaUserWorkstations | Here you can give a comma-separated list of machines on which the user is allowed to login. You may observe problems when you try to connect to a Samba domain member. Because domain members are not in this list, the domain controllers will reject them. Where this attribute is omitted, the default implies no restrictions. |
sambaSID | The security identifier(SID) of the user. The Windows equivalent of UNIX UIDs. |
sambaPrimaryGroupSID | The security identifier (SID) of the primary group of the user. |
sambaDomainName | Domain the user is part of. |
The majority of these parameters are only used when Samba is acting as a PDC of a domain (refer to Domain Control, for details on how to configure Samba as a PDC). The following four attributes are only stored with the sambaSamAccount entry if the values are non-default values:
These attributes are only stored with the sambaSamAccount entry if
the values are non-default values. For example, assume MORIA has now been
configured as a PDC and that logon home = \\%L\%u was defined in
its smb.conf
file. When a user named “becky” logs on to the domain,
the logon home string is expanded to \\MORIA\becky.
If the smbHome attribute exists in the entry “uid=becky,ou=People,dc=samba,dc=org”,
this value is used. However, if this attribute does not exist, then the value
of the logon home parameter is used in its place. Samba
will only write the attribute value to the directory entry if the value is
something other than the default (e.g., \\MOBY\becky
).
The following is a working LDIF that demonstrates the use of the SambaSamAccount ObjectClass:
dn: uid=guest2, ou=People,dc=quenya,dc=org sambaLMPassword: 878D8014606CDA29677A44EFA1353FC7 sambaPwdMustChange: 2147483647 sambaPrimaryGroupSID: S-1-5-21-2447931902-1787058256-3961074038-513 sambaNTPassword: 552902031BEDE9EFAAD3B435B51404EE sambaPwdLastSet: 1010179124 sambaLogonTime: 0 objectClass: sambaSamAccount uid: guest2 sambaKickoffTime: 2147483647 sambaAcctFlags: [UX ] sambaLogoffTime: 2147483647 sambaSID: S-1-5-21-2447931902-1787058256-3961074038-5006 sambaPwdCanChange: 0
The following is an LDIF entry for using both the sambaSamAccount and posixAccount ObjectClasses:
dn: uid=gcarter, ou=People,dc=quenya,dc=org sambaLogonTime: 0 displayName: Gerald Carter sambaLMPassword: 552902031BEDE9EFAAD3B435B51404EE sambaPrimaryGroupSID: S-1-5-21-2447931902-1787058256-3961074038-1201 objectClass: posixAccount objectClass: sambaSamAccount sambaAcctFlags: [UX ] userPassword: {crypt}BpM2ej8Rkzogo uid: gcarter uidNumber: 9000 cn: Gerald Carter loginShell: /bin/bash logoffTime: 2147483647 gidNumber: 100 sambaKickoffTime: 2147483647 sambaPwdLastSet: 1010179230 sambaSID: S-1-5-21-2447931902-1787058256-3961074038-5004 homeDirectory: /home/moria/gcarter sambaPwdCanChange: 0 sambaPwdMustChange: 2147483647 sambaNTPassword: 878D8014606CDA29677A44EFA1353FC7
Samba-3 and later can update the non-Samba (LDAP) password stored with an account. When using pam_ldap, this allows changing both UNIX and Windows passwords at once.
The ldap passwd sync options can have the values shown in Possible ldap passwd sync Values.
Table 10.4. Possible ldap passwd sync
Values
Value | Description |
---|---|
yes | When the user changes his password, update
|
no | Only update |
only | Only update the LDAP password and let the LDAP server worry about the other fields. This option is only available on some LDAP servers and only when the LDAP server supports LDAP_EXOP_X_MODIFY_PASSWD. |
More information can be found in the smb.conf
man page.
Howard Chu has written a special overlay called smbk5pwd. This tool modifies the
SambaNTPassword
, SambaLMPassword
and Heimdal
hashes in an OpenLDAP entry when an LDAP_EXOP_X_MODIFY_PASSWD operation is performed.
The overlay is shipped with OpenLDAP-2.3 and can be found in the
contrib/slapd-modules/smbk5pwd
subdirectory. This module can also be used with
OpenLDAP-2.2.
Every so often someone comes along with what seems (to them) like a great new idea. Storing user accounts in an SQL backend is one of them. Those who want to do this are in the best position to know what the specific benefits are to them. This may sound like a cop-out, but in truth we cannot document every little detail of why certain things of marginal utility to the bulk of Samba users might make sense to the rest. In any case, the following instructions should help the determined SQL user to implement a working system. These account storage methods are not actively maintained by the Samba Team.
You can set up your own table and specify the field names to pdb_mysql (see
MySQL field names for MySQL passdb backend for
the column names) or use the default table. The file
examples/pdb/mysql/mysql.dump
contains the correct queries to
create the required tables. Use the command:
root#
mysql -u
username
-hhostname
-ppassword
\databasename
</path/to/samba/examples/pdb/mysql/mysql.dump
This plug-in lacks some good documentation, but here is some brief information. Add the following to the
passdb backend variable in your smb.conf
:
passdb backend = [other-plugins] mysql:identifier [other-plugins] |
The identifier can be any string you like, as long as it does not collide with the identifiers of other plugins or other instances of pdb_mysql. If you specify multiple pdb_mysql.so entries in passdb backend, you also need to use different identifiers.
Additional options can be given through the smb.conf
file in the [global]
section.
Refer to Basic smb.conf Options for MySQL passdb Backend.
Table 10.5. Basic smb.conf Options for MySQL passdb Backend
Field | Contents |
---|---|
mysql host | Host name, defaults to `localhost' |
mysql password | |
mysql user | Defaults to `samba' |
mysql database | Defaults to `samba' |
mysql port | Defaults to 3306 |
table | Name of the table containing the users |
Since the password for the MySQL user is stored in the smb.conf
file, you should make the smb.conf
file
readable only to the user who runs Samba. This is considered a security bug and will soon be fixed.
Names of the columns are given in MySQL field names for MySQL passdb backend. The default column names can be found in the example table dump.
Table 10.6. MySQL field names for MySQL passdb backend
You can put a colon (:) after the name of each column, which
should specify the column to update when updating the table. You can also specify nothing behind the colon, in which case the field data will not be updated. Setting a column name to NULL
means the field should not be used.
An example configuration is shown in Example Configuration for the MySQL passdb Backend.
Example 10.3. Example Configuration for the MySQL passdb Backend
I strongly discourage the use of plaintext passwords; however, you can use them.
If you would like to use plaintext passwords, set `identifier:lanman pass column' and `identifier:nt pass column' to `NULL' (without the quotes) and `identifier:plain pass column' to the name of the column containing the plaintext passwords.
If you use encrypted passwords, set the 'identifier:plain pass column' to 'NULL' (without the quotes). This is the default.
It is possible to have not all data in the database by making some "constant."
For example, you can set `identifier:fullname column' to something like CONCAT(Firstname,' ',Surname)
Or, set `identifier:workstations column' to: NULL
.See the MySQL documentation for more language constructs.
“I've installed Samba, but now I can't log on with my UNIX account! ”
Make sure your user has been added to the current Samba passdb backend. Read the Account Management Tools, for details.
A few complaints have been received from users who just moved to Samba-3. The following
smb.conf
file entries were causing problems: new accounts were being added to the old
smbpasswd file, not to the tdbsam passdb.tdb file:
[global] |
... |
passdb backend = smbpasswd, tdbsam |
... |
Samba will add new accounts to the first entry in the passdb backend parameter entry. If you want to update to the tdbsam, then change the entry to:
passdb backend = tdbsam, smbpasswd |