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SMB.CONF(5) File Formats and Conventions SMB.CONF(5)

NAME
smb.conf - The configuration file for the Samba suite

SYNOPSIS
The smb.conf file is a configuration file for the Samba suite.
smb.conf contains runtime configuration information for the Samba
programs. The complete description of the file format and possible
parameters held within are here for reference purposes.

HOW CONFIGURATION CHANGES ARE APPLIED
The Samba suite includes a number of different programs. Some of them
operate in a client mode, others are server daemons that provide
various services to its clients. The smb.conf file is processed in the
following way:

o The Samba suite's client applications read their
configuration only once. Any changes made after start aren't
reflected in the context of already running client code.

o The Samba suite's server daemons reload their configuration
when requested. However, already active connections do not
change their configuration. More detailed information can be
found in smbd(8) and winbindd(8) manual pages.

To request Samba server daemons to refresh their configuration, please
use smbcontrol(1) utility.

FILE FORMAT
The file consists of sections and parameters. A section begins with the
name of the section in square brackets and continues until the next
section begins. Sections contain parameters of the form:

name = value

The file is line-based - that is, each newline-terminated line
represents either a comment, a section name or a parameter.

Section and parameter names are not case sensitive.

Only the first equals sign in a parameter is significant. Whitespace
before or after the first equals sign is discarded. Leading, trailing
and internal whitespace in section and parameter names is irrelevant.
Leading and trailing whitespace in a parameter value is discarded.
Internal whitespace within a parameter value is retained verbatim.

Any line beginning with a semicolon (";") or a hash ("#") character is
ignored, as are lines containing only whitespace.

Any line ending in a "\" is continued on the next line in the customary
UNIX fashion.

The values following the equals sign in parameters are all either a
string (no quotes needed) or a boolean, which may be given as yes/no,
1/0 or true/false. Case is not significant in boolean values, but is
preserved in string values. Some items such as create masks are
numeric.

SECTION DESCRIPTIONS
Each section in the configuration file (except for the [global]
section) describes a shared resource (known as a "share"). The section
name is the name of the shared resource and the parameters within the
section define the shares attributes.

There are three special sections, [global], [homes] and [printers],
which are described under special sections. The following notes apply
to ordinary section descriptions.

A share consists of a directory to which access is being given plus a
description of the access rights which are granted to the user of the
service. Some housekeeping options are also specifiable.

Sections are either file share services (used by the client as an
extension of their native file systems) or printable services (used by
the client to access print services on the host running the server).

Sections may be designated guest services, in which case no password is
required to access them. A specified UNIX guest account is used to
define access privileges in this case.

Sections other than guest services will require a password to access
them. The client provides the username. As older clients only provide
passwords and not usernames, you may specify a list of usernames to
check against the password using the user = option in the share
definition. For modern clients such as Windows 95/98/ME/NT/2000, this
should not be necessary.

The access rights granted by the server are masked by the access rights
granted to the specified or guest UNIX user by the host system. The
server does not grant more access than the host system grants.

The following sample section defines a file space share. The user has
write access to the path /home/bar. The share is accessed via the share
name foo:

[foo]
path = /home/bar
read only = no

The following sample section defines a printable share. The share is
read-only, but printable. That is, the only write access permitted is
via calls to open, write to and close a spool file. The guest ok
parameter means access will be permitted as the default guest user
(specified elsewhere):

[aprinter]
path = /var/tmp
read only = yes
printable = yes
guest ok = yes

SPECIAL SECTIONS
The [global] section
Parameters in this section apply to the server as a whole, or are
defaults for sections that do not specifically define certain items.
See the notes under PARAMETERS for more information.

The [homes] section
If a section called [homes] is included in the configuration file,
services connecting clients to their home directories can be created on
the fly by the server.

When the connection request is made, the existing sections are scanned.
If a match is found, it is used. If no match is found, the requested
section name is treated as a username and looked up in the local
password file. If the name exists and the correct password has been
given, a share is created by cloning the [homes] section.

Some modifications are then made to the newly created share:

o The share name is changed from homes to the located
username.

o If no path was given, the path is set to the user's home
directory.

If you decide to use a path = line in your [homes] section, it may be
useful to use the %S macro. For example:

path = /data/pchome/%S

is useful if you have different home directories for your PCs than for
UNIX access.

This is a fast and simple way to give a large number of clients access
to their home directories with a minimum of fuss.

A similar process occurs if the requested section name is "homes",
except that the share name is not changed to that of the requesting
user. This method of using the [homes] section works well if different
users share a client PC.

The [homes] section can specify all the parameters a normal service
section can specify, though some make more sense than others. The
following is a typical and suitable [homes] section:

[homes]
read only = no

An important point is that if guest access is specified in the [homes]
section, all home directories will be visible to all clients without a
password. In the very unlikely event that this is actually desirable,
it is wise to also specify read only access.

The browseable flag for auto home directories will be inherited from
the global browseable flag, not the [homes] browseable flag. This is
useful as it means setting browseable = no in the [homes] section will
hide the [homes] share but make any auto home directories visible.

The [printers] section
This section works like [homes], but for printers.

If a [printers] section occurs in the configuration file, users are
able to connect to any printer specified in the local host's printcap
file.

When a connection request is made, the existing sections are scanned.
If a match is found, it is used. If no match is found, but a [homes]
section exists, it is used as described above. Otherwise, the requested
section name is treated as a printer name and the appropriate printcap
file is scanned to see if the requested section name is a valid printer
share name. If a match is found, a new printer share is created by
cloning the [printers] section.

A few modifications are then made to the newly created share:

o The share name is set to the located printer name

o If no printer name was given, the printer name is set to the
located printer name

o If the share does not permit guest access and no username
was given, the username is set to the located printer name.

The [printers] service MUST be printable - if you specify otherwise,
the server will refuse to load the configuration file.

Typically the path specified is that of a world-writeable spool
directory with the sticky bit set on it. A typical [printers] entry
looks like this:

[printers]
path = /var/tmp
guest ok = yes
printable = yes

All aliases given for a printer in the printcap file are legitimate
printer names as far as the server is concerned. If your printing
subsystem doesn't work like that, you will have to set up a
pseudo-printcap. This is a file consisting of one or more lines like
this:

alias|alias|alias|alias...

Each alias should be an acceptable printer name for your printing
subsystem. In the [global] section, specify the new file as your
printcap. The server will only recognize names found in your
pseudo-printcap, which of course can contain whatever aliases you like.
The same technique could be used simply to limit access to a subset of
your local printers.

An alias, by the way, is defined as any component of the first entry of
a printcap record. Records are separated by newlines, components (if
there are more than one) are separated by vertical bar symbols (|).

Note

On SYSV systems which use lpstat to determine what printers are
defined on the system you may be able to use printcap name = lpstat
to automatically obtain a list of printers. See the printcap name
option for more details.

USERSHARES
Starting with Samba version 3.0.23 the capability for non-root users to
add, modify, and delete their own share definitions has been added.
This capability is called usershares and is controlled by a set of
parameters in the [global] section of the smb.conf. The relevant
parameters are :

usershare allow guests
Controls if usershares can permit guest access.

usershare max shares
Maximum number of user defined shares allowed.

usershare owner only
If set only directories owned by the sharing user can be shared.

usershare path
Points to the directory containing the user defined share
definitions. The filesystem permissions on this directory control
who can create user defined shares.

usershare prefix allow list
Comma-separated list of absolute pathnames restricting what
directories can be shared. Only directories below the pathnames in
this list are permitted.

usershare prefix deny list
Comma-separated list of absolute pathnames restricting what
directories can be shared. Directories below the pathnames in this
list are prohibited.

usershare template share
Names a pre-existing share used as a template for creating new
usershares. All other share parameters not specified in the user
defined share definition are copied from this named share.

To allow members of the UNIX group foo to create user defined shares,
create the directory to contain the share definitions as follows:

Become root:

mkdir /usr/local/samba/lib/usershares
chgrp foo /usr/local/samba/lib/usershares
chmod 1770 /usr/local/samba/lib/usershares

Then add the parameters

usershare path = /usr/local/samba/lib/usershares
usershare max shares = 10 # (or the desired number of shares)

to the global section of your smb.conf. Members of the group foo may
then manipulate the user defined shares using the following commands.

net usershare add sharename path [comment] [acl] [guest_ok=[y|n]]
To create or modify (overwrite) a user defined share.

net usershare delete sharename
To delete a user defined share.

net usershare list wildcard-sharename
To list user defined shares.

net usershare info wildcard-sharename
To print information about user defined shares.

PARAMETERS
Parameters define the specific attributes of sections.

Some parameters are specific to the [global] section (e.g., security).
Some parameters are usable in all sections (e.g., create mask). All
others are permissible only in normal sections. For the purposes of the
following descriptions the [homes] and [printers] sections will be
considered normal. The letter G in parentheses indicates that a
parameter is specific to the [global] section. The letter S indicates
that a parameter can be specified in a service specific section. All S
parameters can also be specified in the [global] section - in which
case they will define the default behavior for all services.

Parameters are arranged here in alphabetical order - this may not
create best bedfellows, but at least you can find them! Where there are
synonyms, the preferred synonym is described, others refer to the
preferred synonym.

VARIABLE SUBSTITUTIONS
Many of the strings that are settable in the config file can take
substitutions. For example the option "path = /tmp/%u" is interpreted
as "path = /tmp/john" if the user connected with the username john.

These substitutions are mostly noted in the descriptions below, but
there are some general substitutions which apply whenever they might be
relevant. These are:

%U
session username (the username that the client wanted, not
necessarily the same as the one they got).

%G
primary group name of %U.

%h
the Internet hostname that Samba is running on.

%m
the NetBIOS name of the client machine (very useful).

This parameter is not available when Samba listens on port 445, as
clients no longer send this information. If you use this macro in
an include statement on a domain that has a Samba domain controller
be sure to set in the [global] section smb ports = 139. This will
cause Samba to not listen on port 445 and will permit include
functionality to function as it did with Samba 2.x.

%L
the NetBIOS name of the server. This allows you to change your
config based on what the client calls you. Your server can have a
"dual personality".

%M
the Internet name of the client machine.

%R
the selected protocol level after protocol negotiation. It can be
one of CORE, COREPLUS, LANMAN1, LANMAN2, NT1, SMB2_02, SMB2_10,
SMB3_00, SMB3_02, SMB3_11 or SMB2_FF.

%d
the process id of the current server process.

%a
The architecture of the remote machine. It currently recognizes
Samba (Samba), the Linux CIFS file system (CIFSFS), OS/2, (OS2),
Mac OS X (OSX), Windows for Workgroups (WfWg), Windows 9x/ME
(Win95), Windows NT (WinNT), Windows 2000 (Win2K), Windows XP
(WinXP), Windows XP 64-bit(WinXP64), Windows 2003 including 2003R2
(Win2K3), and Windows Vista (Vista). Anything else will be known as
UNKNOWN.

%I
the IP address of the client machine.

Before 4.0.0 it could contain IPv4 mapped IPv6 addresses, now it
only contains IPv4 or IPv6 addresses.

%J
the IP address of the client machine, colons/dots replaced by
underscores.

%i
the local IP address to which a client connected.

Before 4.0.0 it could contain IPv4 mapped IPv6 addresses, now it
only contains IPv4 or IPv6 addresses.

%j
the local IP address to which a client connected, colons/dots
replaced by underscores.

%T
the current date and time.

%t
the current date and time in a minimal format without colons
(YYYYYmmdd_HHMMSS).

%D
name of the domain or workgroup of the current user.

%w
the winbind separator.

%$(envvar)
the value of the environment variable envar.

The following substitutes apply only to some configuration options
(only those that are used when a connection has been established):

%S
the name of the current service, if any.

%P
the root directory of the current service, if any.

%u
username of the current service, if any.

%g
primary group name of %u.

%H
the home directory of the user given by %u.

%N
This value is the same as %L.

There are some quite creative things that can be done with these
substitutions and other smb.conf options.

NAME MANGLING
Samba supports name mangling so that DOS and Windows clients can use
files that don't conform to the 8.3 format. It can also be set to
adjust the case of 8.3 format filenames.

There are several options that control the way mangling is performed,
and they are grouped here rather than listed separately. For the
defaults look at the output of the testparm program.

These options can be set separately for each service.

The options are:

case sensitive = yes/no/auto
controls whether filenames are case sensitive. If they aren't,
Samba must do a filename search and match on passed names. The
default setting of auto allows clients that support case sensitive
filenames (Linux CIFSVFS and smbclient 3.0.5 and above currently)
to tell the Samba server on a per-packet basis that they wish to
access the file system in a case-sensitive manner (to support UNIX
case sensitive semantics). No Windows or DOS system supports
case-sensitive filename so setting this option to auto is that same
as setting it to no for them. Default auto.

default case = upper/lower
controls what the default case is for new filenames (ie. files that
don't currently exist in the filesystem). Default lower. IMPORTANT
NOTE: As part of the optimizations for directories containing large
numbers of files, the following special case applies. If the
options case sensitive = yes, preserve case = No, and short
preserve case = No are set, then the case of all incoming client
filenames, not just new filenames, will be modified. See additional
notes below.

preserve case = yes/no
controls whether new files (ie. files that don't currently exist in
the filesystem) are created with the case that the client passes,
or if they are forced to be the default case. Default yes.

short preserve case = yes/no
controls if new files (ie. files that don't currently exist in the
filesystem) which conform to 8.3 syntax, that is all in upper case
and of suitable length, are created upper case, or if they are
forced to be the default case. This option can be used with
preserve case = yes to permit long filenames to retain their case,
while short names are lowercased. Default yes.

By default, Samba 3.0 has the same semantics as a Windows NT server, in
that it is case insensitive but case preserving. As a special case for
directories with large numbers of files, if the case options are set as
follows, "case sensitive = yes", "case preserve = no", "short preserve
case = no" then the "default case" option will be applied and will
modify all filenames sent from the client when accessing this share.

REGISTRY-BASED CONFIGURATION
Starting with Samba version 3.2.0, the capability to store Samba
configuration in the registry is available. The configuration is stored
in the registry key HKLM\Software\Samba\smbconf. There are two levels
of registry configuration:

1. Share definitions stored in registry are used. This is
triggered by setting the global parameter registry shares to
"yes" in smb.conf.

The registry shares are loaded not at startup but on demand
at runtime by smbd. Shares defined in smb.conf take priority
over shares of the same name defined in registry.

2. Global smb.conf options stored in registry are used. This
can be activated in two different ways:

Firstly, a registry only configuration is triggered by
setting config backend = registry in the [global] section of
smb.conf. This resets everything that has been read from
config files to this point and reads the content of the
global configuration section from the registry. This is the
recommended method of using registry based configuration.

Secondly, a mixed configuration can be activated by a
special new meaning of the parameter include = registry in
the [global] section of smb.conf. This reads the global
options from registry with the same priorities as for an
include of a text file. This may be especially useful in
cases where an initial configuration is needed to access the
registry.

Activation of global registry options automatically
activates registry shares. So in the registry only case,
shares are loaded on demand only.

Note: To make registry-based configurations foolproof at least to a
certain extent, the use of lock directory and config backend inside the
registry configuration has been disabled: Especially by changing the
lock directory inside the registry configuration, one would create a
broken setup where the daemons do not see the configuration they loaded
once it is active.

The registry configuration can be accessed with tools like regedit or
net (rpc) registry in the key HKLM\Software\Samba\smbconf. More
conveniently, the conf subcommand of the net(8) utility offers a
dedicated interface to read and write the registry based configuration
locally, i.e. directly accessing the database file, circumventing the
server.

IDENTITY MAPPING CONSIDERATIONS
In the SMB protocol, users, groups, and machines are represented by
their security identifiers (SIDs). On POSIX system Samba processes need
to run under corresponding POSIX user identities and with supplemental
POSIX groups to allow access to the files owned by those users and
groups. The process of mapping SIDs to POSIX users and groups is called
IDENTITY MAPPING or, in short, ID MAPPING.

Samba supports multiple ways to map SIDs to POSIX users and groups. The
configuration is driven by the idmap config DOMAIN : OPTION option
which allows one to specify identity mapping (idmap) options for each
domain separately.

Identity mapping modules implement different strategies for mapping of
SIDs to POSIX user and group identities. They are applicable to
different use cases and scenarios. It is advised to read the
documentation of the individual identity mapping modules before
choosing a specific scenario to use. Each identity management module is
documented in a separate manual page. The standard idmap backends are
tdb (idmap_tdb(8)), tdb2 (idmap_tdb2(8)), ldap (idmap_ldap(8)), rid
(idmap_rid(8)), hash (idmap_hash(8)), autorid (idmap_autorid(8)), ad
(idmap_ad(8)), nss (idmap_nss(8)), and rfc2307 (idmap_rfc2307(8)).

Overall, ID mapping configuration should be decided carefully. Changes
to the already deployed ID mapping configuration may create the risk of
losing access to the data or disclosing the data to the wrong parties.

This example shows how to configure two domains with idmap_rid(8), the
principal domain and a trusted domain, leaving the default id mapping
scheme at tdb.

[global]
security = domain
workgroup = MAIN

idmap config * : backend = tdb
idmap config * : range = 1000000-1999999

idmap config MAIN : backend = rid
idmap config MAIN : range = 5000000-5999999

idmap config TRUSTED : backend = rid
idmap config TRUSTED : range = 6000000-6999999

EXPLANATION OF EACH PARAMETER
abort shutdown script (G)

This a full path name to a script called by smbd(8) that should
stop a shutdown procedure issued by the shutdown script.

If the connected user possesses the SeRemoteShutdownPrivilege,
right, this command will be run as root.

Default: abort shutdown script = ""

Example: abort shutdown script = /sbin/shutdown -c

access based share enum (S)

If this parameter is yes for a service, then the share hosted by
the service will only be visible to users who have read or write
access to the share during share enumeration (for example net view
\\sambaserver). The share ACLs which allow or deny the access to
the share can be modified using for example the sharesec command or
using the appropriate Windows tools. This has parallels to access
based enumeration, the main difference being that only share
permissions are evaluated, and security descriptors on files
contained on the share are not used in computing enumeration access
rights.

Default: access based share enum = no

acl allow execute always (S)

This boolean parameter controls the behaviour of smbd(8) when
receiving a protocol request of "open for execution" from a Windows
client. With Samba 3.6 and older, the execution right in the ACL
was not checked, so a client could execute a file even if it did
not have execute rights on the file. In Samba 4.0, this has been
fixed, so that by default, i.e. when this parameter is set to
"False", "open for execution" is now denied when execution
permissions are not present.

If this parameter is set to "True", Samba does not check execute
permissions on "open for execution", thus re-establishing the
behaviour of Samba 3.6. This can be useful to smoothen upgrades
from older Samba versions to 4.0 and newer. This setting is not
meant to be used as a permanent setting, but as a temporary relief:
It is recommended to fix the permissions in the ACLs and reset this
parameter to the default after a certain transition period.

Default: acl allow execute always = no

acl check permissions (S)

Please note this parameter is now deprecated in Samba 3.6.2 and
will be removed in a future version of Samba.

This boolean parameter controls what smbd(8) does on receiving a
protocol request of "open for delete" from a Windows client. If a
Windows client doesn't have permissions to delete a file then they
expect this to be denied at open time. POSIX systems normally only
detect restrictions on delete by actually attempting to delete the
file or directory. As Windows clients can (and do) "back out" a
delete request by unsetting the "delete on close" bit Samba cannot
delete the file immediately on "open for delete" request as we
cannot restore such a deleted file. With this parameter set to true
(the default) then smbd checks the file system permissions directly
on "open for delete" and denies the request without actually
deleting the file if the file system permissions would seem to deny
it. This is not perfect, as it's possible a user could have deleted
a file without Samba being able to check the permissions correctly,
but it is close enough to Windows semantics for mostly correct
behaviour. Samba will correctly check POSIX ACL semantics in this
case.

If this parameter is set to "false" Samba doesn't check permissions
on "open for delete" and allows the open. If the user doesn't have
permission to delete the file this will only be discovered at close
time, which is too late for the Windows user tools to display an
error message to the user. The symptom of this is files that appear
to have been deleted "magically" re-appearing on a Windows explorer
refresh. This is an extremely advanced protocol option which should
not need to be changed. This parameter was introduced in its final
form in 3.0.21, an earlier version with slightly different
semantics was introduced in 3.0.20. That older version is not
documented here.

Default: acl check permissions = yes

acl flag inherited canonicalization (S)

This option controls the way Samba handles client requests setting
the Security Descriptor of files and directories and the effect the
operation has on the Security Descriptor flag "DACL auto-inherited"
(DI). Generally, this flag is set on a file (or directory) upon
creation if the parent directory has DI set and also has
inheritable ACEs.

On the other hand when a Security Descriptor is explicitly set on a
file, the DI flag is cleared, unless the flag "DACL Inheritance
Required" (DR) is also set in the new Security Descriptor (fwiw, DR
is never stored on disk).

This is the default behaviour when this option is enabled (the
default). When setting this option to no, the resulting value of
the DI flag on-disk is directly taken from the DI value of the
to-be-set Security Descriptor. This can be used so dump tools like
rsync that copy data blobs from xattrs that represent ACLs created
by the acl_xattr VFS module will result in copies of the ACL that
are identical to the source. Without this option, the copied ACLs
would all loose the DI flag if set on the source.

Default: acl flag inherited canonicalization = yes

acl group control (S)

In a POSIX filesystem, only the owner of a file or directory and
the superuser can modify the permissions and ACLs on a file. If
this parameter is set, then Samba overrides this restriction, and
also allows the primary group owner of a file or directory to
modify the permissions and ACLs on that file.

On a Windows server, groups may be the owner of a file or directory
- thus allowing anyone in that group to modify the permissions on
it. This allows the delegation of security controls on a point in
the filesystem to the group owner of a directory and anything below
it also owned by that group. This means there are multiple people
with permissions to modify ACLs on a file or directory, easing
manageability.

This parameter allows Samba to also permit delegation of the
control over a point in the exported directory hierarchy in much
the same way as Windows. This allows all members of a UNIX group to
control the permissions on a file or directory they have group
ownership on.

This parameter is best used with the inherit owner option and also
on a share containing directories with the UNIX setgid bit set on
them, which causes new files and directories created within it to
inherit the group ownership from the containing directory.

This parameter was deprecated in Samba 3.0.23, but re-activated in
Samba 3.0.31 and above, as it now only controls permission changes
if the user is in the owning primary group. It is now no longer
equivalent to the dos filemode option.

Default: acl group control = no

acl map full control (S)

This boolean parameter controls whether smbd(8) maps a POSIX ACE
entry of "rwx" (read/write/execute), the maximum allowed POSIX
permission set, into a Windows ACL of "FULL CONTROL". If this
parameter is set to true any POSIX ACE entry of "rwx" will be
returned in a Windows ACL as "FULL CONTROL", is this parameter is
set to false any POSIX ACE entry of "rwx" will be returned as the
specific Windows ACL bits representing read, write and execute.

Default: acl map full control = yes

ad dc functional level (G)

The value of the parameter (a string) is the Active Directory
functional level that this Domain Controller will claim to support.

Possible values are :

o 2008_R2: Similar to Windows 2008 R2 Functional Level

o 2012: Similar to Windows 2012 Functional Level

o 2012_R2: Similar to Windows 2012 R2 Functional Level

o 2016: Similar to Windows 2016 Functional Level

Normally this option should not be set as Samba will operate per
the released functionality of the Samba Active Directory Domain
Controller.

However to access incomplete features in domain functional level
2016 it may be useful to set this value, prior to upgrading the
domain functional level.

If this is set manually, the protection against mismatching
features between domain controllers is reduced, so all domain
controllers should be running the same version of Samba, to ensure
that behaviour as seen by the client is the same no matter which DC
is contacted.

Setting this to 2016 will allow raising the domain functional level
with samba-tool domain level raise --domain-level=2016 and provide
access to Samba's Kerberos Claims and Dynamic Access Control
feature.

Warning
The Samba's Kerberos Claims and Dynamic Access Control features
enabled with 2016 are incomplete in Samba 4.19.
Default: ad dc functional level = 2008_R2

Example: ad dc functional level = 2016

add group script (G)

This is the full pathname to a script that will be run AS ROOT by
smbd(8) when a new group is requested. It will expand any %g to the
group name passed. This script is only useful for installations
using the Windows NT domain administration tools. The script is
free to create a group with an arbitrary name to circumvent unix
group name restrictions. In that case the script must print the
numeric gid of the created group on stdout.

Default: add group script =

Example: add group script = /usr/sbin/groupadd %g

additional dns hostnames (G)

A list of additional DNS names by which this host can be identified

Default: additional dns hostnames = # empty string (no additional
dns names)

Example: additional dns hostnames = host2.example.com
host3.other.com

add machine script (G)

This is the full pathname to a script that will be run by smbd(8)
when a machine is added to Samba's domain and a Unix account
matching the machine's name appended with a "$" does not already
exist.

This option is very similar to the add user script, and likewise
uses the %u substitution for the account name. Do not use the %m
substitution.

Default: add machine script =

Example: add machine script = /usr/sbin/adduser -n -g machines -c
Machine -d /var/lib/nobody -s /bin/false %u

addport command (G)

Samba 3.0.23 introduced support for adding printer ports remotely
using the Windows "Add Standard TCP/IP Port Wizard". This option
defines an external program to be executed when smbd receives a
request to add a new Port to the system. The script is passed two
parameters:

o port name

o device URI

The deviceURI is in the format of
socket://<hostname>[:<portnumber>] or lpd://<hostname>/<queuename>.

Default: addport command =

Example: addport command = /etc/samba/scripts/addport.sh

addprinter command (G)

With the introduction of MS-RPC based printing support for Windows
NT/2000 clients in Samba 2.2, The MS Add Printer Wizard (APW) icon
is now also available in the "Printers..." folder displayed a share
listing. The APW allows for printers to be add remotely to a Samba
or Windows NT/2000 print server.

For a Samba host this means that the printer must be physically
added to the underlying printing system. The addprinter command
defines a script to be run which will perform the necessary
operations for adding the printer to the print system and to add
the appropriate service definition to the smb.conf file in order
that it can be shared by smbd(8).

The addprinter command is automatically invoked with the following
parameter (in order):

o printer name

o share name

o port name

o driver name

o location

o Windows 9x driver location

All parameters are filled in from the PRINTER_INFO_2 structure sent
by the Windows NT/2000 client with one exception. The "Windows 9x
driver location" parameter is included for backwards compatibility
only. The remaining fields in the structure are generated from
answers to the APW questions.

Once the addprinter command has been executed, smbd will reparse
the smb.conf to determine if the share defined by the APW exists.
If the sharename is still invalid, then smbd will return an
ACCESS_DENIED error to the client.

The addprinter command program can output a single line of text,
which Samba will set as the port the new printer is connected to.
If this line isn't output, Samba won't reload its printer shares.

Default: addprinter command =

Example: addprinter command = /usr/bin/addprinter

add share command (G)

Samba 2.2.0 introduced the ability to dynamically add and delete
shares via the Windows NT 4.0 Server Manager. The add share command
is used to define an external program or script which will add a
new service definition to smb.conf.

In order to successfully execute the add share command, smbd
requires that the administrator connects using a root account (i.e.
uid == 0) or has the SeDiskOperatorPrivilege. Scripts defined in
the add share command parameter are executed as root.

When executed, smbd will automatically invoke the add share command
with five parameters.

o configFile - the location of the global smb.conf file.

o shareName - the name of the new share.

o pathName - path to an **existing** directory on disk.

o comment - comment string to associate with the new
share.

o max connections Number of maximum simultaneous
connections to this share.

This parameter is only used to add file shares. To add printer
shares, see the addprinter command.

Default: add share command =

Example: add share command = /usr/local/bin/addshare

add user script (G)

This is the full pathname to a script that will be run AS ROOT by
smbd(8) under special circumstances described below.

Normally, a Samba server requires that UNIX users are created for
all users accessing files on this server. For sites that use
Windows NT account databases as their primary user database
creating these users and keeping the user list in sync with the
Windows NT PDC is an onerous task. This option allows smbd to
create the required UNIX users ON DEMAND when a user accesses the
Samba server.

When the Windows user attempts to access the Samba server, at login
(session setup in the SMB protocol) time, smbd(8) contacts the
password server and attempts to authenticate the given user with
the given password. If the authentication succeeds then smbd
attempts to find a UNIX user in the UNIX password database to map
the Windows user into. If this lookup fails, and add user script is
set then smbd will call the specified script AS ROOT, expanding any
%u argument to be the user name to create.

If this script successfully creates the user then smbd will
continue on as though the UNIX user already existed. In this way,
UNIX users are dynamically created to match existing Windows NT
accounts.

See also security, password server, delete user script.

Default: add user script =

Example: add user script = /usr/local/samba/bin/add_user %u

add user to group script (G)

Full path to the script that will be called when a user is added to
a group using the Windows NT domain administration tools. It will
be run by smbd(8) AS ROOT. Any %g will be replaced with the group
name and any %u will be replaced with the user name.

Note that the adduser command used in the example below does not
support the used syntax on all systems.

Default: add user to group script =

Example: add user to group script = /usr/sbin/adduser %u %g

administrative share (S)

If this parameter is set to yes for a share, then the share will be
an administrative share. The Administrative Shares are the default
network shares created by all Windows NT-based operating systems.
These are shares like C$, D$ or ADMIN$. The type of these shares is
STYPE_DISKTREE_HIDDEN.

See the section below on security for more information about this
option.

Default: administrative share = no

admin users (S)

This is a list of users who will be granted administrative
privileges on the share. This means that they will do all file
operations as the super-user (root).

You should use this option very carefully, as any user in this list
will be able to do anything they like on the share, irrespective of
file permissions.

Default: admin users =

Example: admin users = jason

afs share (S)

This parameter controls whether special AFS features are enabled
for this share. If enabled, it assumes that the directory exported
via the path parameter is a local AFS import. The special AFS
features include the attempt to hand-craft an AFS token if you
enabled --with-fake-kaserver in configure.

Default: afs share = no

afs token lifetime (G)

This parameter controls the lifetime of tokens that the AFS
fake-kaserver claims. In reality these never expire but this
lifetime controls when the afs client will forget the token.

Set this parameter to 0 to get NEVERDATE.

Default: afs token lifetime = 604800

afs username map (G)

If you are using the fake kaserver AFS feature, you might want to
hand-craft the usernames you are creating tokens for. For example
this is necessary if you have users from several domain in your AFS
Protection Database. One possible scheme to code users as
DOMAIN+User as it is done by winbind with the + as a separator.

The mapped user name must contain the cell name to log into, so
without setting this parameter there will be no token.

Default: afs username map =

Example: afs username map = %u@afs.samba.org

aio max threads (G)

The integer parameter specifies the maximum number of threads each
smbd process will create when doing parallel asynchronous IO calls.
If the number of outstanding calls is greater than this number the
requests will not be refused but go onto a queue and will be
scheduled in turn as outstanding requests complete.

Related command: aio read size

Related command: aio write size

Default: aio max threads = 100

aio read size (S)

If this integer parameter is set to a non-zero value, Samba will
read from files asynchronously when the request size is bigger than
this value. Note that it happens only for non-chained and
non-chaining reads.

The only reasonable values for this parameter are 0 (no async I/O)
and 1 (always do async I/O).

Related command: aio write size

Default: aio read size = 1

Example: aio read size = 0 # Always do reads synchronously

aio write behind (S)

If Samba has been built with asynchronous I/O support, Samba will
not wait until write requests are finished before returning the
result to the client for files listed in this parameter. Instead,
Samba will immediately return that the write request has been
finished successfully, no matter if the operation will succeed or
not. This might speed up clients without aio support, but is really
dangerous, because data could be lost and files could be damaged.

The syntax is identical to the veto files parameter.

Default: aio write behind =

Example: aio write behind = /*.tmp/

aio write size (S)

If this integer parameter is set to a non-zero value, Samba will
write to files asynchronously when the request size is bigger than
this value. Note that it happens only for non-chained and
non-chaining writes.

The only reasonable values for this parameter are 0 (no async I/O)
and 1 (always do async I/O).

Compared to aio read size this parameter has a smaller effect, most
writes should end up in the file system cache. Writes that require
space allocation might benefit most from going asynchronous.

Related command: aio read size

Default: aio write size = 1

Example: aio write size = 0 # Always do writes synchronously

algorithmic rid base (G)

This determines how Samba will use its algorithmic mapping from
uids/gid to the RIDs needed to construct NT Security Identifiers.

Setting this option to a larger value could be useful to sites
transitioning from WinNT and Win2k, as existing user and group rids
would otherwise clash with system users etc.

All UIDs and GIDs must be able to be resolved into SIDs for the
correct operation of ACLs on the server. As such the algorithmic
mapping can't be 'turned off', but pushing it 'out of the way'
should resolve the issues. Users and groups can then be assigned
'low' RIDs in arbitrary-rid supporting backends.

Default: algorithmic rid base = 1000

Example: algorithmic rid base = 100000

allocation roundup size (S)

This parameter allows an administrator to tune the allocation size
reported to Windows clients. This is only useful for old SMB1
clients because modern SMB dialects eliminated that bottleneck and
have better performance by default. Using this parameter may cause
difficulties for some applications, e.g. MS Visual Studio. If the
MS Visual Studio compiler starts to crash with an internal error,
set this parameter to zero for this share. Settings this parameter
to a large value can also cause small files to allocate more space
on the disk than needed.

This parameter is deprecated and will be removed in one of the next
Samba releases.

The integer parameter specifies the roundup size in bytes.

Default: allocation roundup size = 0

Example: allocation roundup size = 1048576 # (to set it to the
former default of 1 MiB)

allow dcerpc auth level connect (G)

This option controls whether DCERPC services are allowed to be used
with DCERPC_AUTH_LEVEL_CONNECT, which provides authentication, but
no per message integrity nor privacy protection.

Some interfaces like samr, lsarpc and netlogon have a hard-coded
default of no and epmapper, mgmt and rpcecho have a hard-coded
default of yes.

The behavior can be overwritten per interface name (e.g. lsarpc,
netlogon, samr, srvsvc, winreg, wkssvc ...) by using 'allow dcerpc
auth level connect:interface = yes' as option.

This option is over-ridden by the implementation specific
restrictions. E.g. the drsuapi and backupkey protocols require
DCERPC_AUTH_LEVEL_PRIVACY. The dnsserver protocol requires
DCERPC_AUTH_LEVEL_INTEGRITY.

Default: allow dcerpc auth level connect = no

Example: allow dcerpc auth level connect = yes

allow dns updates (G)

This option determines what kind of updates to the DNS are allowed.

DNS updates can either be disallowed completely by setting it to
disabled, enabled over secure connections only by setting it to
secure only or allowed in all cases by setting it to nonsecure.

Default: allow dns updates = secure only

Example: allow dns updates = disabled

allow insecure wide links (G)

In normal operation the option wide links which allows the server
to follow symlinks outside of a share path is automatically
disabled when unix extensions are enabled on a Samba server. This
is done for security purposes to prevent UNIX clients creating
symlinks to areas of the server file system that the administrator
does not wish to export.

Setting allow insecure wide links to true disables the link between
these two parameters, removing this protection and allowing a site
to configure the server to follow symlinks (by setting wide links
to "true") even when unix extensions is turned on.

It is not recommended to enable this option unless you fully
understand the implications of allowing the server to follow
symbolic links created by UNIX clients. For most normal Samba
configurations this would be considered a security hole and setting
this parameter is not recommended.

This option was added at the request of sites who had deliberately
set Samba up in this way and needed to continue supporting this
functionality without having to patch the Samba code.

Default: allow insecure wide links = no

allow nt4 crypto (G)

This option is deprecated and will be removed in future, as it is a
security problem if not set to "no" (which will be the hardcoded
behavior in future).

This option controls whether the netlogon server (currently only in
'active directory domain controller' mode), will reject clients
which do not support NETLOGON_NEG_STRONG_KEYS nor
NETLOGON_NEG_SUPPORTS_AES.

This option was added with Samba 4.2.0. It may lock out clients
which worked fine with Samba versions up to 4.1.x. as the effective
default was "yes" there, while it is "no" now.

If you have clients without RequireStrongKey = 1 in the registry,
you may need to set "allow nt4 crypto = yes", until you have fixed
all clients.

"allow nt4 crypto = yes" allows weak crypto to be negotiated, maybe
via downgrade attacks.

Avoid using this option! Use explicit 'allow nt4
crypto:COMPUTERACCOUNT = yes' instead! Which is available with the
patches for CVE-2022-38023 see
https://bugzilla.samba.org/show_bug.cgi?id=15240

Samba will log an error in the log files at log level 0 if legacy a
client is rejected or allowed without an explicit, 'allow nt4
crypto:COMPUTERACCOUNT = yes' option for the client. The message
will indicate the explicit 'allow nt4 crypto:COMPUTERACCOUNT = yes'
line to be added, if the legacy client software requires it. (The
log level can be adjusted with 'CVE_2022_38023:error_debug_level =
1' in order to complain only at a higher log level).

This allows admins to use "yes" only for a short grace period, in
order to collect the explicit 'allow nt4 crypto:COMPUTERACCOUNT =
yes' options.

This option is over-ridden by the effective value of 'yes' from the
'server reject md5 schannel:COMPUTERACCOUNT' and/or 'reject md5
clients' options.

Default: allow nt4 crypto = no

allow nt4 crypto:COMPUTERACCOUNT (G)

If you still have legacy domain members which required 'allow nt4
crypto = yes', it is possible to specify an explicit exception per
computer account by using 'allow nt4 crypto:COMPUTERACCOUNT = yes'
as option. Note that COMPUTERACCOUNT has to be the sAMAccountName
value of the computer account (including the trailing '$' sign).

Samba will log a complaint in the log files at log level 0 about
the security problem if the option is set to "yes", but the related
computer does not require it. (The log level can be adjusted with
'CVE_2022_38023:warn_about_unused_debug_level = 1' in order to
complain only at a higher log level).

Samba will log a warning in the log files at log level 5, if a
setting is still needed for the specified computer account.

See CVE-2022-38023,
https://bugzilla.samba.org/show_bug.cgi?id=15240.

This option overrides the allow nt4 crypto option.

This option is over-ridden by the effective value of 'yes' from the
'server reject md5 schannel:COMPUTERACCOUNT' and/or 'reject md5
clients' options.

Which means 'allow nt4 crypto:COMPUTERACCOUNT = yes' is only useful
in combination with 'server reject md5 schannel:COMPUTERACCOUNT =
no'

allow nt4 crypto:LEGACYCOMPUTER1$ = yes
server reject md5 schannel:LEGACYCOMPUTER1$ = no
allow nt4 crypto:NASBOX$ = yes
server reject md5 schannel:NASBOX$ = no
allow nt4 crypto:LEGACYCOMPUTER2$ = yes
server reject md5 schannel:LEGACYCOMPUTER2$ = no

No default

allow trusted domains (G)

This option only takes effect when the security option is set to
server, domain or ads. If it is set to no, then attempts to connect
to a resource from a domain or workgroup other than the one which
smbd is running in will fail, even if that domain is trusted by the
remote server doing the authentication.

This is useful if you only want your Samba server to serve
resources to users in the domain it is a member of. As an example,
suppose that there are two domains DOMA and DOMB. DOMB is trusted
by DOMA, which contains the Samba server. Under normal
circumstances, a user with an account in DOMB can then access the
resources of a UNIX account with the same account name on the Samba
server even if they do not have an account in DOMA. This can make
implementing a security boundary difficult.

Default: allow trusted domains = yes

allow unsafe cluster upgrade (G)

If set to no (the default), smbd checks at startup if other smbd
versions are running in the cluster and refuses to start if so.
This is done to protect data corruption in internal data structures
due to incompatible Samba versions running concurrently in the same
cluster. Setting this parameter to yes disables this safety check.

Default: allow unsafe cluster upgrade = no

apply group policies (G)

This option controls whether winbind will execute the gpupdate
command defined in gpo update command on the Group Policy update
interval. The Group Policy update interval is defined as every 90
minutes, plus a random offset between 0 and 30 minutes. This
applies Group Policy Machine polices to the client or KDC and
machine policies to a server.

Default: apply group policies = no

Example: apply group policies = yes

async dns timeout (G)

The number of seconds the asynchronous DNS resolver code in Samba
will wait for responses. Some of the Samba client library code uses
internal asynchronous DNS resolution for A and AAAA records when
trying to find Active Directory Domain controllers. This value
prevents this name resolution code from waiting for DNS server
timeouts.

The minimum value of this parameter is clamped at 1 second.

Default: async dns timeout = 10

Example: async dns timeout = 20

async smb echo handler (G)

This parameter specifies whether Samba should fork the async smb
echo handler. It can be beneficial if your file system can block
syscalls for a very long time. In some circumstances, it prolongs
the timeout that Windows uses to determine whether a connection is
dead. This parameter is only for SMB1. For SMB2 and above TCP
keepalives can be used instead.

Default: async smb echo handler = no

auth event notification (G)

When enabled, this option causes Samba (acting as an Active
Directory Domain Controller) to stream authentication events across
the internal message bus. Scripts built using Samba's python
bindings can listen to these events by registering as the service
auth_event.

This is not needed for the audit logging described in log level.

Instead, this should instead be considered a developer option (it
assists in the Samba testsuite) rather than a facility for external
auditing, as message delivery is not guaranteed (a feature that the
testsuite works around).

The authentication events are also logged via the normal logging
methods when the log level is set appropriately, say to
auth_json_audit:3.

Default: auth event notification = no

preload

This parameter is a synonym for auto services.

auto services (G)

This is a list of services that you want to be automatically added
to the browse lists. This is most useful for homes and printers
services that would otherwise not be visible.

Note that if you just want all printers in your printcap file
loaded then the load printers option is easier.

Default: auto services =

Example: auto services = fred lp colorlp

available (S)

This parameter lets you "turn off" a service. If available = no,
then ALL attempts to connect to the service will fail. Such
failures are logged.

Default: available = yes

bind dns directory

This parameter is a synonym for binddns dir.

binddns dir (G)

This parameters defines the directory samba will use to store the
configuration files for bind, such as named.conf. NOTE: The bind
dns directory needs to be on the same mount point as the private
directory!

Default: binddns dir = ${prefix}/bind-dns

bind interfaces only (G)

This global parameter allows the Samba admin to limit what
interfaces on a machine will serve SMB requests. It affects file
service smbd(8) and name service nmbd(8) in a slightly different
ways.

For name service it causes nmbd to bind to ports 137 and 138 on the
interfaces listed in the interfaces parameter. nmbd also binds to
the "all addresses" interface (0.0.0.0) on ports 137 and 138 for
the purposes of reading broadcast messages. If this option is not
set then nmbd will service name requests on all of these sockets.
If bind interfaces only is set then nmbd will check the source
address of any packets coming in on the broadcast sockets and
discard any that don't match the broadcast addresses of the
interfaces in the interfaces parameter list. As unicast packets are
received on the other sockets it allows nmbd to refuse to serve
names to machines that send packets that arrive through any
interfaces not listed in the interfaces list. IP Source address
spoofing does defeat this simple check, however, so it must not be
used seriously as a security feature for nmbd.

For file service it causes smbd(8) to bind only to the interface
list given in the interfaces parameter. This restricts the networks
that smbd will serve, to packets coming in on those interfaces.
Note that you should not use this parameter for machines that are
serving PPP or other intermittent or non-broadcast network
interfaces as it will not cope with non-permanent interfaces.

If bind interfaces only is set and the network address 127.0.0.1 is
not added to the interfaces parameter list smbpasswd(8) may not
work as expected due to the reasons covered below.

To change a users SMB password, the smbpasswd by default connects
to the localhost - 127.0.0.1 address as an SMB client to issue the
password change request. If bind interfaces only is set then unless
the network address 127.0.0.1 is added to the interfaces parameter
list then smbpasswd will fail to connect in it's default mode.
smbpasswd can be forced to use the primary IP interface of the
local host by using its smbpasswd(8) -r remote machine parameter,
with remote machine set to the IP name of the primary interface of
the local host.

Default: bind interfaces only = no

blocking locks (S)

This parameter controls the behavior of smbd(8) when given a
request by a client to obtain a byte range lock on a region of an
open file, and the request has a time limit associated with it.

If this parameter is set and the lock range requested cannot be
immediately satisfied, samba will internally queue the lock
request, and periodically attempt to obtain the lock until the
timeout period expires.

If this parameter is set to no, then samba will behave as previous
versions of Samba would and will fail the lock request immediately
if the lock range cannot be obtained.

Default: blocking locks = yes

block size (S)

This parameter controls the behavior of smbd(8) when reporting disk
free sizes. By default, this reports a disk block size of 1024
bytes.

Changing this parameter may have some effect on the efficiency of
client writes, this is not yet confirmed. This parameter was added
to allow advanced administrators to change it (usually to a higher
value) and test the effect it has on client write performance
without re-compiling the code. As this is an experimental option it
may be removed in a future release.

Changing this option does not change the disk free reporting size,
just the block size unit reported to the client.

Default: block size = 1024

Example: block size = 4096

browsable

This parameter is a synonym for browseable.

browseable (S)

This controls whether this share is seen in the list of available
shares in a net view and in the browse list.

Default: browseable = yes

browse list (G)

This controls whether smbd(8) will serve a browse list to a client
doing a NetServerEnum call. Normally set to yes. You should never
need to change this.

Default: browse list = yes

cache directory (G)

Usually, most of the TDB files are stored in the lock directory.
Since Samba 3.4.0, it is possible to differentiate between TDB
files with persistent data and TDB files with non-persistent data
using the state directory and the cache directory options.

This option specifies the directory for storing TDB files
containing non-persistent data that will be kept across service
restarts. The directory should be placed on persistent storage, but
the data can be safely deleted by an administrator.

Default: cache directory = ${prefix}/var/cache

Example: cache directory = /var/run/samba/locks/cache

casesignames

This parameter is a synonym for case sensitive.

case sensitive (S)

See the discussion in the section name mangling.

Default: case sensitive = auto

change notify (G)

This parameter specifies whether Samba should reply to a client's
file change notify requests.

You should never need to change this parameter

Default: change notify = yes

change share command (G)

Samba 2.2.0 introduced the ability to dynamically add and delete
shares via the Windows NT 4.0 Server Manager. The change share
command is used to define an external program or script which will
modify an existing service definition in smb.conf.

In order to successfully execute the change share command, smbd
requires that the administrator connects using a root account (i.e.
uid == 0) or has the SeDiskOperatorPrivilege. Scripts defined in
the change share command parameter are executed as root.

When executed, smbd will automatically invoke the change share
command with six parameters.

o configFile - the location of the global smb.conf file.

o shareName - the name of the new share.

o pathName - path to an **existing** directory on disk.

o comment - comment string to associate with the new
share.

o max connections Number of maximum simultaneous
connections to this share.

o CSC policy - client side caching policy in string form.
Valid values are: manual, documents, programs, disable.

This parameter is only used to modify existing file share
definitions. To modify printer shares, use the "Printers..." folder
as seen when browsing the Samba host.

Default: change share command =

Example: change share command = /usr/local/bin/changeshare

check parent directory delete on close (S)

A Windows SMB server prevents the client from creating files in a
directory that has the delete-on-close flag set. By default Samba
doesn't perform this check as this check is a quite expensive
operation in Samba.

Default: check parent directory delete on close = no

check password script (G)

The name of a program that can be used to check password
complexity. The password is sent to the program's standard input.

The program must return 0 on a good password, or any other value if
the password is bad. In case the password is considered weak (the
program does not return 0) the user will be notified and the
password change will fail.

In Samba AD, this script will be run AS ROOT by samba(8) without
any substitutions.

Note that starting with Samba 4.11 the following environment
variables are exported to the script:

o SAMBA_CPS_ACCOUNT_NAME is always present and contains
the sAMAccountName of user, the is the same as the %u
substitutions in the none AD DC case.

o SAMBA_CPS_USER_PRINCIPAL_NAME is optional in the AD DC
case if the userPrincipalName is present.

o SAMBA_CPS_FULL_NAME is optional if the displayName is
present.

Note: In the example directory is a sample program called
crackcheck that uses cracklib to check the password quality.

Default: check password script = # Disabled

Example: check password script = /usr/local/sbin/crackcheck

cldap port (G)

This option controls the port used by the CLDAP protocol.

Default: cldap port = 389

Example: cldap port = 3389

client ipc max protocol (G)

The value of the parameter (a string) is the highest protocol level
that will be supported for IPC$ connections as DCERPC transport.

Normally this option should not be set as the automatic negotiation
phase in the SMB protocol takes care of choosing the appropriate
protocol.

The value default refers to the latest supported protocol,
currently SMB3_11.

See client max protocol for a full list of available protocols. The
values CORE, COREPLUS, LANMAN1, LANMAN2 are silently upgraded to
NT1.

Default: client ipc max protocol = default

Example: client ipc max protocol = SMB2_10

client ipc min protocol (G)

This setting controls the minimum protocol version that the will be
attempted to use for IPC$ connections as DCERPC transport.

Normally this option should not be set as the automatic negotiation
phase in the SMB protocol takes care of choosing the appropriate
protocol.

The value default refers to the higher value of NT1 and the
effective value of client min protocol.

See client max protocol for a full list of available protocols. The
values CORE, COREPLUS, LANMAN1, LANMAN2 are silently upgraded to
NT1.

Default: client ipc min protocol = default

Example: client ipc min protocol = SMB3_11

client ipc signing (G)

This controls whether the client is allowed or required to use SMB
signing for IPC$ connections as DCERPC transport. Possible values
are desired, required and disabled.

When set to required or default, SMB signing is mandatory.

When set to desired, SMB signing is offered, but not enforced and
if set to disabled, SMB signing is not offered either.

Connections from winbindd to Active Directory Domain Controllers
always enforce signing.

Default: client ipc signing = default

client lanman auth (G)

This parameter has been deprecated since Samba 4.13 and support for
LanMan (as distinct from NTLM, NTLMv2 or Kerberos) authentication
as a client will be removed in a future Samba release.

That is, in the future, the current default of client NTLMv2 auth =
yes will be the enforced behaviour.

This parameter determines whether or not smbclient(8) and other
samba client tools will attempt to authenticate itself to servers
using the weaker LANMAN password hash. If disabled, only server
which support NT password hashes (e.g. Windows NT/2000, Samba,
etc... but not Windows 95/98) will be able to be connected from the
Samba client.

The LANMAN encrypted response is easily broken, due to its
case-insensitive nature, and the choice of algorithm. Clients
without Windows 95/98 servers are advised to disable this option.

Disabling this option will also disable the client plaintext auth
option.

Likewise, if the client ntlmv2 auth parameter is enabled, then only
NTLMv2 logins will be attempted.

Default: client lanman auth = no

client ldap sasl wrapping (G)

The client ldap sasl wrapping defines whether ldap traffic will be
signed or signed and encrypted (sealed). Possible values are plain,
sign and seal.

The values sign and seal are only available if Samba has been
compiled against a modern OpenLDAP version (2.3.x or higher).

This option is needed firstly to secure the privacy of
administrative connections from samba-tool, including in particular
new or reset passwords for users. For this reason the default is
seal.

Additionally, winbindd and the net tool can use LDAP to communicate
with Domain Controllers, so this option also controls the level of
privacy for those connections. All supported AD DC versions will
enforce the usage of at least signed LDAP connections by default,
so a value of at least sign is required in practice.

The default value is seal. That implies synchronizing the time with
the KDC in the case of using Kerberos.

Default: client ldap sasl wrapping = seal

client max protocol (G)

The value of the parameter (a string) is the highest protocol level
that will be supported by the client.

Possible values are :

o CORE: Earliest version. No concept of user names.

o COREPLUS: Slight improvements on CORE for efficiency.

o LANMAN1: First modern version of the protocol. Long
filename support.

o LANMAN2: Updates to Lanman1 protocol.

o NT1: Current up to date version of the protocol. Used by
Windows NT. Known as CIFS.

o SMB2: Re-implementation of the SMB protocol. Used by
Windows Vista and later versions of Windows. SMB2 has
sub protocols available.

o SMB2_02: The earliest SMB2 version.

o SMB2_10: Windows 7 SMB2 version.

By default SMB2 selects the SMB2_10 variant.

o SMB3: The same as SMB2. Used by Windows 8. SMB3 has sub
protocols available.

o SMB3_00: Windows 8 SMB3 version.

o SMB3_02: Windows 8.1 SMB3 version.

o SMB3_11: Windows 10 SMB3 version.

By default SMB3 selects the SMB3_11 variant.

Normally this option should not be set as the automatic negotiation
phase in the SMB protocol takes care of choosing the appropriate
protocol.

The value default refers to SMB3_11.

IPC$ connections for DCERPC e.g. in winbindd, are handled by the
client ipc max protocol option.

Default: client max protocol = default

Example: client max protocol = LANMAN1

client min protocol (G)

This setting controls the minimum protocol version that the client
will attempt to use.

Normally this option should not be set as the automatic negotiation
phase in the SMB protocol takes care of choosing the appropriate
protocol unless you connect to a legacy SMB1-only server.

See Related command: client max protocol for a full list of
available protocols.

IPC$ connections for DCERPC e.g. in winbindd, are handled by the
client ipc min protocol option.

Note that most command line tools support --option='client min
protocol=NT1', so it may not be required to enable SMB1 protocols
globally in smb.conf.

Default: client min protocol = SMB2_02

Example: client min protocol = NT1

client NTLMv2 auth (G)

This parameter has been deprecated since Samba 4.13 and support for
NTLM and LanMan (as distinct from NTLMv2 or Kerberos
authentication) will be removed in a future Samba release.

That is, in the future, the current default of client NTLMv2 auth =
yes will be the enforced behaviour.

This parameter determines whether or not smbclient(8) will attempt
to authenticate itself to servers using the NTLMv2 encrypted
password response.

If enabled, only an NTLMv2 and LMv2 response (both much more secure
than earlier versions) will be sent. Older servers (including NT4 <
SP4, Win9x and Samba 2.2) are not compatible with NTLMv2 when not
in an NTLMv2 supporting domain

Similarly, if enabled, NTLMv1, client lanman auth and client
plaintext auth authentication will be disabled. This also disables
share-level authentication.

If disabled, an NTLM response (and possibly a LANMAN response) will
be sent by the client, depending on the value of client lanman
auth.

Note that Windows Vista and later versions already use NTLMv2 by
default, and some sites (particularly those following 'best
practice' security polices) only allow NTLMv2 responses, and not
the weaker LM or NTLM.

When client use spnego is also set to yes extended security
(SPNEGO) is required in order to use NTLMv2 only within NTLMSSP.
This behavior was introduced with the patches for CVE-2016-2111.

Default: client NTLMv2 auth = yes

client plaintext auth (G)

This parameter has been deprecated since Samba 4.13 and support for
plaintext (as distinct from NTLM, NTLMv2 or Kerberos
authentication) will be removed in a future Samba release.

That is, in the future, the current default of client plaintext
auth = no will be the enforced behaviour.

Specifies whether a client should send a plaintext password if the
server does not support encrypted passwords.

Default: client plaintext auth = no

client protection (G)

This parameter defines which protection Samba client tools should
use by default.

Possible client settings are:

o default - Use the individual default values of the
options:

o client signing

o client smb encrypt

o plain - This will send everything just as plaintext,
signing or encryption are turned off.

o sign - This will enable integrity checking.

o encrypt - This will enable integrity checks and force
encryption for privacy.

Default: client protection = default

client schannel (G)

This option is deprecated with Samba 4.8 and will be removed in
future. At the same time the default changed to yes, which will be
the hardcoded behavior in future.

This controls whether the client offers or even demands the use of
the netlogon schannel. client schannel = no does not offer the
schannel, client schannel = auto offers the schannel but does not
enforce it, and client schannel = yes denies access if the server
is not able to speak netlogon schannel.

Note that for active directory domains this is hardcoded to client
schannel = yes.

This option is over-ridden by the require strong key option.

Default: client schannel = yes

Example: client schannel = auto

client signing (G)

This controls whether the client is allowed or required to use SMB
signing. Possible values are desired, required and disabled.

When set to desired or default, SMB signing is offered, but not
enforced.

When set to required, SMB signing is mandatory and if set to
disabled, SMB signing is not offered either.

IPC$ connections for DCERPC e.g. in winbindd, are handled by the
client ipc signing option.

Default: client signing = default

client smb encrypt (G)

This parameter controls whether a client should try or is required
to use SMB encryption. It has different effects depending on
whether the connection uses SMB1 or SMB3:

o If the connection uses SMB1, then this option controls
the use of a Samba-specific extension to the SMB
protocol introduced in Samba 3.2 that makes use of the
Unix extensions.

o If the connection uses SMB2 or newer, then this option
controls the use of the SMB-level encryption that is
supported in SMB version 3.0 and above and available in
Windows 8 and newer.

This parameter can be set globally. Possible values are off,
if_required, desired, and required. A special value is default
which is the implicit default setting of if_required.

Effects for SMB1
The Samba-specific encryption of SMB1 connections is an
extension to the SMB protocol negotiated as part of the UNIX
extensions. SMB encryption uses the GSSAPI (SSPI on Windows)
ability to encrypt and sign every request/response in a SMB
protocol stream. When enabled it provides a secure method of
SMB/CIFS communication, similar to an ssh protected session,
but using SMB/CIFS authentication to negotiate encryption and
signing keys. Currently this is only supported smbclient of by
Samba 3.2 and newer. Windows does not support this feature.

When set to default, SMB encryption is probed, but not
enforced. When set to required, SMB encryption is required and
if set to disabled, SMB encryption can not be negotiated.

Effects for SMB3 and newer
Native SMB transport encryption is available in SMB version 3.0
or newer. It is only used by Samba if client max protocol is
set to SMB3 or newer.

These features can be controlled with settings of client smb
encrypt as follows:

o Leaving it as default, explicitly setting default,
or setting it to if_required globally will enable
negotiation of encryption but will not turn on data
encryption globally.

o Setting it to desired globally will enable
negotiation and will turn on data encryption on
sessions and share connections for those servers
that support it.

o Setting it to required globally will enable
negotiation and turn on data encryption on sessions
and share connections. Clients that do not support
encryption will be denied access to the server.

o Setting it to off globally will completely disable
the encryption feature for all connections.

Default: client smb encrypt = default

client smb3 encryption algorithms (G)

This parameter specifies the availability and order of encryption
algorithms which are available for negotiation in the SMB3_11
dialect.

It is also possible to remove individual algorithms from the
default list, by prefixing them with '-'. This can avoid having to
specify a hardcoded list.

Note: that the removal of AES-128-CCM from the list will result in
SMB3_00 and SMB3_02 being unavailable, as it is the default and
only available algorithm for these dialects.

Default: client smb3 encryption algorithms = AES-128-GCM,
AES-128-CCM, AES-256-GCM, AES-256-CCM

Example: client smb3 encryption algorithms = AES-256-GCM

Example: client smb3 encryption algorithms = -AES-128-GCM
-AES-128-CCM

client smb3 signing algorithms (G)

This parameter specifies the availability and order of signing
algorithms which are available for negotiation in the SMB3_11
dialect.

It is also possible to remove individual algorithms from the
default list, by prefixing them with '-'. This can avoid having to
specify a hardcoded list.

Note: that the removal of AES-128-CMAC from the list will result in
SMB3_00 and SMB3_02 being unavailable, and the removal of
HMAC-SHA256 will result in SMB2_02 and SMB2_10 being unavailable,
as these are the default and only available algorithms for these
dialects.

Default: client smb3 signing algorithms = AES-128-GMAC,
AES-128-CMAC, HMAC-SHA256

Example: client smb3 signing algorithms = AES-128-CMAC, HMAC-SHA256

Example: client smb3 signing algorithms = -AES-128-CMAC

client use kerberos (G)

This parameter determines whether Samba client tools will try to
authenticate using Kerberos. For Kerberos authentication you need
to use dns names instead of IP addresses when connecting to a
service.

Possible option settings are:

o desired - Kerberos authentication will be tried first
and if it fails it automatically fallback to NTLM.

o required - Kerberos authentication will be required.
There will be no falllback to NTLM or a different
alternative.

o off - Don't use Kerberos, use NTLM instead or another
alternative.

In case that weak cryptography is not allowed (e.g. FIPS mode) the
default will be forced to required.

Default: client use kerberos = desired

client use spnego principal (G)

This parameter determines whether or not smbclient(8) and other
samba components acting as a client will attempt to use the
server-supplied principal sometimes given in the SPNEGO exchange.

If enabled, Samba can attempt to use Kerberos to contact servers
known only by IP address. Kerberos relies on names, so ordinarily
cannot function in this situation.

This is a VERY BAD IDEA for security reasons, and so this parameter
SHOULD NOT BE USED. It will be removed in a future version of
Samba.

If disabled, Samba will use the name used to look up the server
when asking the KDC for a ticket. This avoids situations where a
server may impersonate another, soliciting authentication as one
principal while being known on the network as another.

Note that Windows XP SP2 and later versions already follow this
behaviour, and Windows Vista and later servers no longer supply
this 'rfc4178 hint' principal on the server side.

This parameter is deprecated in Samba 4.2.1 and will be removed
(along with the functionality) in a later release of Samba.

Default: client use spnego principal = no

client use spnego (G)

This parameter has been deprecated since Samba 4.13 and support for
NTLMv2, NTLM and LanMan authentication outside NTLMSSP will be
removed in a future Samba release.

That is, in the future, the current default of client use spnego =
yes will be the enforced behaviour.

This variable controls whether Samba clients will try to use Simple
and Protected NEGOtiation (as specified by rfc2478) with supporting
servers (including WindowsXP, Windows2000 and Samba 3.0) to agree
upon an authentication mechanism. This enables Kerberos
authentication in particular.

When client NTLMv2 auth is also set to yes extended security
(SPNEGO) is required in order to use NTLMv2 only within NTLMSSP.
This behavior was introduced with the patches for CVE-2016-2111.

Default: client use spnego = yes

cluster addresses (G)

With this parameter you can add additional addresses that nmbd will
register with a WINS server. Similarly, these addresses will be
registered by default when net ads dns register is called with
clustering = yes configured.

Default: cluster addresses =

Example: cluster addresses = 10.0.0.1 10.0.0.2 10.0.0.3

clustering (G)

This parameter specifies whether Samba should contact ctdb for
accessing its tdb files and use ctdb as a backend for its messaging
backend.

Set this parameter to yes only if you have a cluster setup with
ctdb running.

Default: clustering = no

comment (S)

This is a text field that is seen next to a share when a client
does a queries the server, either via the network neighborhood or
via net view to list what shares are available.

If you want to set the string that is displayed next to the machine
name then see the server string parameter.

Default: comment = # No comment

Example: comment = Fred's Files

config backend (G)

This controls the backend for storing the configuration. Possible
values are file (the default) and registry. When config backend =
registry is encountered while loading smb.conf, the configuration
read so far is dropped and the global options are read from
registry instead. So this triggers a registry only configuration.
Share definitions are not read immediately but instead registry
shares is set to yes.

Note: This option can not be set inside the registry configuration
itself.

Default: config backend = file

Example: config backend = registry

config file (G)

This allows you to override the config file to use, instead of the
default (usually smb.conf). There is a chicken and egg problem here
as this option is set in the config file!

For this reason, if the name of the config file has changed when
the parameters are loaded then it will reload them from the new
config file.

This option takes the usual substitutions, which can be very
useful.

If the config file doesn't exist then it won't be loaded (allowing
you to special case the config files of just a few clients).

No default

Example: config file = /usr/local/samba/lib/smb.conf.%m

copy (S)

This parameter allows you to "clone" service entries. The specified
service is simply duplicated under the current service's name. Any
parameters specified in the current section will override those in
the section being copied.

This feature lets you set up a 'template' service and create
similar services easily. Note that the service being copied must
occur earlier in the configuration file than the service doing the
copying.

Default: copy =

Example: copy = otherservice

create krb5 conf (G)

Setting this parameter to no prevents winbind from creating custom
krb5.conf files. Winbind normally does this because the krb5
libraries are not AD-site-aware and thus would pick any domain
controller out of potentially very many. Winbind is site-aware and
makes the krb5 libraries use a local DC by creating its own
krb5.conf files.

Preventing winbind from doing this might become necessary if you
have to add special options into your system-krb5.conf that winbind
does not see.

Default: create krb5 conf = yes

create mode

This parameter is a synonym for create mask.

create mask (S)

When a file is created, the necessary permissions are calculated
according to the mapping from DOS modes to UNIX permissions, and
the resulting UNIX mode is then bit-wise 'AND'ed with this
parameter. This parameter may be thought of as a bit-wise MASK for
the UNIX modes of a file. Any bit not set here will be removed from
the modes set on a file when it is created.

The default value of this parameter removes the group and other
write and execute bits from the UNIX modes.

Following this Samba will bit-wise 'OR' the UNIX mode created from
this parameter with the value of the force create mode parameter
which is set to 000 by default.

This parameter does not affect directory masks. See the parameter
directory mask for details.

Default: create mask = 0744

Example: create mask = 0775

csc policy (S)

This stands for client-side caching policy, and specifies how
clients capable of offline caching will cache the files in the
share. The valid values are: manual, documents, programs, disable.

These values correspond to those used on Windows servers.

For example, shares containing roaming profiles can have offline
caching disabled using csc policy = disable.

Default: csc policy = manual

Example: csc policy = programs

ctdbd socket (G)

If you set clustering=yes, you need to tell Samba where ctdbd
listens on its unix domain socket. The default path as of ctdb 1.0
is /tmp/ctdb.socket which you have to explicitly set for Samba in
smb.conf.

Default: ctdbd socket =

Example: ctdbd socket = /tmp/ctdb.socket

ctdb locktime warn threshold (G)

In a cluster environment using Samba and ctdb it is critical that
locks on central ctdb-hosted databases like locking.tdb are not
held for long. With the current Samba architecture it happens that
Samba takes a lock and while holding that lock makes file system
calls into the shared cluster file system. This option makes Samba
warn if it detects that it has held locks for the specified number
of milliseconds. If this happens, smbd will emit a debug level 0
message into its logs and potentially into syslog. The most likely
reason for such a log message is that an operation of the cluster
file system Samba exports is taking longer than expected. The
messages are meant as a debugging aid for potential cluster
problems.

The default value of 0 disables this logging.

Default: ctdb locktime warn threshold = 0

ctdb timeout (G)

This parameter specifies a timeout in milliseconds for the
connection between Samba and ctdb. It is only valid if you have
compiled Samba with clustering and if you have set clustering=yes.

When something in the cluster blocks, it can happen that we wait
indefinitely long for ctdb, just adding to the blocking condition.
In a well-running cluster this should never happen, but there are
too many components in a cluster that might have hickups. Choosing
the right balance for this value is very tricky, because on a busy
cluster long service times to transfer something across the cluster
might be valid. Setting it too short will degrade the service your
cluster presents, setting it too long might make the cluster itself
not recover from something severely broken for too long.

Be aware that if you set this parameter, this needs to be in the
file smb.conf, it is not really helpful to put this into a registry
configuration (typical on a cluster), because to access the
registry contact to ctdb is required.

Setting ctdb timeout to n makes any process waiting longer than n
milliseconds for a reply by the cluster panic. Setting it to 0 (the
default) makes Samba block forever, which is the highly recommended
default.

Default: ctdb timeout = 0

cups connection timeout (G)

This parameter is only applicable if printing is set to cups.

If set, this option specifies the number of seconds that smbd will
wait whilst trying to contact to the CUPS server. The connection
will fail if it takes longer than this number of seconds.

Default: cups connection timeout = 30

Example: cups connection timeout = 60

cups encrypt (G)

This parameter is only applicable if printing is set to cups and if
you use CUPS newer than 1.0.x.It is used to define whether or not
Samba should use encryption when talking to the CUPS server.
Possible values are auto, yes and no

When set to auto we will try to do a TLS handshake on each CUPS
connection setup. If that fails, we will fall back to unencrypted
operation.

Default: cups encrypt = no

cups options (S)

This parameter is only applicable if printing is set to cups. Its
value is a free form string of options passed directly to the cups
library.

You can pass any generic print option known to CUPS (as listed in
the CUPS "Software Users' Manual"). You can also pass any printer
specific option (as listed in "lpoptions -d printername -l") valid
for the target queue. Multiple parameters should be space-delimited
name/value pairs according to the PAPI text option ABNF
specification. Collection values ("name={a=... b=... c=...}") are
stored with the curley brackets intact.

You should set this parameter to raw if your CUPS server error_log
file contains messages such as "Unsupported format
'application/octet-stream'" when printing from a Windows client
through Samba. It is no longer necessary to enable system wide raw
printing in /etc/cups/mime.{convs,types}.

Default: cups options = ""

Example: cups options = "raw media=a4"

cups server (G)

This parameter is only applicable if printing is set to cups.

If set, this option overrides the ServerName option in the CUPS
client.conf. This is necessary if you have virtual samba servers
that connect to different CUPS daemons.

Optionally, a port can be specified by separating the server name
and port number with a colon. If no port was specified, the default
port for IPP (631) will be used.

Default: cups server = ""

Example: cups server = mycupsserver

Example: cups server = mycupsserver:1631

dcerpc endpoint servers (G)

Specifies which DCE/RPC endpoint servers should be run.

Default: dcerpc endpoint servers = epmapper, wkssvc, samr,
netlogon, lsarpc, drsuapi, dssetup, unixinfo, browser, eventlog6,
backupkey, dnsserver

Example: dcerpc endpoint servers = rpcecho

deadtime (G)

The value of the parameter (a decimal integer) represents the
number of minutes of inactivity before a connection is considered
dead, and it is disconnected. The deadtime only takes effect if the
number of open files is zero.

This is useful to stop a server's resources being exhausted by a
large number of inactive connections.

Most clients have an auto-reconnect feature when a connection is
broken so in most cases this parameter should be transparent to
users.

Using this parameter with a timeout of a few minutes is recommended
for most systems.

A deadtime of zero indicates that no auto-disconnection should be
performed.

Default: deadtime = 10080

Example: deadtime = 15

debug class (G)

With this boolean parameter enabled, the debug class (DBGC_CLASS)
will be displayed in the debug header.

For more information about currently available debug classes, see
section about log level.

Default: debug class = no

debug encryption (G)

This option will make the smbd server and client code using libsmb
(smbclient, smbget, smbspool, ...) dump the Session Id, the
decrypted Session Key, the Signing Key, the Application Key, the
Encryption Key and the Decryption Key every time an SMB3+ session
is established. This information will be printed in logs at level
0.

Warning: access to these values enables the decryption of any
encrypted traffic on the dumped sessions. This option should only
be enabled for debugging purposes.

Default: debug encryption = no

debug hires timestamp (G)

Sometimes the timestamps in the log messages are needed with a
resolution of higher that seconds, this boolean parameter adds
microsecond resolution to the timestamp message header when turned
on.

Note that the parameter debug timestamp or debug syslog format must
be on for this to have an effect.

Default: debug hires timestamp = yes

debug pid (G)

When using only one log file for more then one forked
smbd(8)-process there may be hard to follow which process outputs
which message. This boolean parameter is adds the process-id to the
timestamp message headers in the logfile when turned on.

Note that the parameter debug timestamp must be on for this to have
an effect.

Default: debug pid = no

debug prefix timestamp (G)

With this option enabled, the timestamp message header is prefixed
to the debug message without the filename and function information
that is included with the debug timestamp parameter. This gives
timestamps to the messages without adding an additional line.

Note that this parameter overrides the debug timestamp parameter.

Default: debug prefix timestamp = no

debug syslog format (G)

With this option enabled (yes (alias in_logs) or always), debug
messages are printed in a single-line format like that
traditionally produced by syslog. The timestamp consists of an
abbreviated month, space-padded date, and time including seconds.
This is followed by the hostname and the program name, with the
process-ID in square brackets.

The value always produces this log format even to STDOUT or STDERR

The value no defers to other parameters and typically produces
traditional two-line Samba logs to log files.

If debug hires timestamp is also enabled then an RFC5424 timestamp
is used instead.

Default: debug syslog format = no

winbind debug traceid (G)

With this boolean parameter enabled, the per request unique traceid
will be displayed in the debug header for winbind processes.

Default: winbind debug traceid = no

debug uid (G)

Samba is sometimes run as root and sometime run as the connected
user, this boolean parameter inserts the current euid, egid, uid
and gid to the timestamp message headers in the log file if turned
on.

Note that the parameter debug timestamp must be on for this to have
an effect.

Default: debug uid = no

dedicated keytab file (G)

Specifies the absolute path to the kerberos keytab file when
kerberos method is set to "dedicated keytab".

Default: dedicated keytab file =

Example: dedicated keytab file = /usr/local/etc/krb5.keytab

default case (S)

See the section on name mangling. Also note the short preserve case
parameter.

Default: default case = lower

default devmode (S)

This parameter is only applicable to printable services. When smbd
is serving Printer Drivers to Windows NT/2k/XP clients, each
printer on the Samba server has a Device Mode which defines things
such as paper size and orientation and duplex settings. The device
mode can only correctly be generated by the printer driver itself
(which can only be executed on a Win32 platform). Because smbd is
unable to execute the driver code to generate the device mode, the
default behavior is to set this field to NULL.

Most problems with serving printer drivers to Windows NT/2k/XP
clients can be traced to a problem with the generated device mode.
Certain drivers will do things such as crashing the client's
Explorer.exe with a NULL devmode. However, other printer drivers
can cause the client's spooler service (spoolsv.exe) to die if the
devmode was not created by the driver itself (i.e. smbd generates a
default devmode).

This parameter should be used with care and tested with the printer
driver in question. It is better to leave the device mode to NULL
and let the Windows client set the correct values. Because drivers
do not do this all the time, setting default devmode = yes will
instruct smbd to generate a default one.

For more information on Windows NT/2k printing and Device Modes,
see the MSDN documentation.

Default: default devmode = yes

default

This parameter is a synonym for default service.

default service (G)

This parameter specifies the name of a service which will be
connected to if the service actually requested cannot be found.
Note that the square brackets are NOT given in the parameter value
(see example below).

There is no default value for this parameter. If this parameter is
not given, attempting to connect to a nonexistent service results
in an error.

Typically the default service would be a guest ok, read only
service.

Also note that the apparent service name will be changed to equal
that of the requested service, this is very useful as it allows you
to use macros like %S to make a wildcard service.

Note also that any "_" characters in the name of the service used
in the default service will get mapped to a "/". This allows for
interesting things.

Default: default service =

Example: default service = pub

defer sharing violations (G)

Windows allows specifying how a file will be shared with other
processes when it is opened. Sharing violations occur when a file
is opened by a different process using options that violate the
share settings specified by other processes. This parameter causes
smbd to act as a Windows server does, and defer returning a
"sharing violation" error message for up to one second, allowing
the client to close the file causing the violation in the meantime.

UNIX by default does not have this behaviour.

There should be no reason to turn off this parameter, as it is
designed to enable Samba to more correctly emulate Windows.

Default: defer sharing violations = yes

delete group script (G)

This is the full pathname to a script that will be run AS ROOT by
smbd(8) when a group is requested to be deleted. It will expand any
%g to the group name passed. This script is only useful for
installations using the Windows NT domain administration tools.

Default: delete group script =

deleteprinter command (G)

With the introduction of MS-RPC based printer support for Windows
NT/2000 clients in Samba 2.2, it is now possible to delete a
printer at run time by issuing the DeletePrinter() RPC call.

For a Samba host this means that the printer must be physically
deleted from the underlying printing system. The deleteprinter
command defines a script to be run which will perform the necessary
operations for removing the printer from the print system and from
smb.conf.

The deleteprinter command is automatically called with only one
parameter: printer name.

Once the deleteprinter command has been executed, smbd will reparse
the smb.conf to check that the associated printer no longer exists.
If the sharename is still valid, then smbd will return an
ACCESS_DENIED error to the client.

Default: deleteprinter command =

Example: deleteprinter command = /usr/bin/removeprinter

delete readonly (S)

This parameter allows readonly files to be deleted. This is not
normal DOS semantics, but is allowed by UNIX.

This option may be useful for running applications such as rcs,
where UNIX file ownership prevents changing file permissions, and
DOS semantics prevent deletion of a read only file.

Default: delete readonly = no

delete share command (G)

Samba 2.2.0 introduced the ability to dynamically add and delete
shares via the Windows NT 4.0 Server Manager. The delete share
command is used to define an external program or script which will
remove an existing service definition from smb.conf.

In order to successfully execute the delete share command, smbd
requires that the administrator connects using a root account (i.e.
uid == 0) or has the SeDiskOperatorPrivilege. Scripts defined in
the delete share command parameter are executed as root.

When executed, smbd will automatically invoke the delete share
command with two parameters.

o configFile - the location of the global smb.conf file.

o shareName - the name of the existing service.

This parameter is only used to remove file shares. To delete
printer shares, see the deleteprinter command.

Default: delete share command =

Example: delete share command = /usr/local/bin/delshare

delete user from group script (G)

Full path to the script that will be called when a user is removed
from a group using the Windows NT domain administration tools. It
will be run by smbd(8) AS ROOT. Any %g will be replaced with the
group name and any %u will be replaced with the user name.

Default: delete user from group script =

Example: delete user from group script = /usr/sbin/deluser %u %g

delete user script (G)

This is the full pathname to a script that will be run by smbd(8)
when managing users with remote RPC (NT) tools.

This script is called when a remote client removes a user from the
server, normally using 'User Manager for Domains' or rpcclient.

This script should delete the given UNIX username.

Default: delete user script =

Example: delete user script = /usr/local/samba/bin/del_user %u

delete veto files (S)

This option is used when Samba is attempting to delete a directory
that contains one or more vetoed files or directories or
non-visible files or directories (such as dangling symlinks that
point nowhere). (see the veto files, hide special files, hide
unreadable, hide unwriteable files options). If this option is set
to no (the default) then if a vetoed directory contains any
non-vetoed files or directories then the directory delete will
fail. This is usually what you want.

If this option is set to yes, then Samba will attempt to
recursively delete any files and directories within the vetoed
directory. This can be useful for integration with file serving
systems such as NetAtalk which create meta-files within directories
you might normally veto DOS/Windows users from seeing (e.g.
.AppleDouble)

Setting delete veto files = yes allows these directories to be
transparently deleted when the parent directory is deleted (so long
as the user has permissions to do so).

Default: delete veto files = no

dfree cache time (S)

The dfree cache time should only be used on systems where a problem
occurs with the internal disk space calculations. This has been
known to happen with Ultrix, but may occur with other operating
systems. The symptom that was seen was an error of "Abort Retry
Ignore" at the end of each directory listing.

This is a new parameter introduced in Samba version 3.0.21. It
specifies in seconds the time that smbd will cache the output of a
disk free query. If set to zero (the default) no caching is done.
This allows a heavily loaded server to prevent rapid spawning of
dfree command scripts increasing the load.

By default this parameter is zero, meaning no caching will be done.

No default

Example: dfree cache time = 60

dfree command (S)

The dfree command setting should only be used on systems where a
problem occurs with the internal disk space calculations. This has
been known to happen with Ultrix, but may occur with other
operating systems. The symptom that was seen was an error of "Abort
Retry Ignore" at the end of each directory listing.

This setting allows the replacement of the internal routines to
calculate the total disk space and amount available with an
external routine. The example below gives a possible script that
might fulfill this function.

In Samba version 3.0.21 this parameter has been changed to be a
per-share parameter, and in addition the parameter dfree cache time
was added to allow the output of this script to be cached for
systems under heavy load.

The external program will be passed a single parameter indicating a
directory in the filesystem being queried. This will typically
consist of the string ./. The script should return two integers in
ASCII. The first should be the total disk space in blocks, and the
second should be the number of available blocks. An optional third
return value can give the block size in bytes. The default
blocksize is 1024 bytes.

Note: Your script should NOT be setuid or setgid and should be
owned by (and writeable only by) root!

Where the script dfree (which must be made executable) could be:

#!/bin/sh
df "$1" | tail -1 | awk '{print $(NF-4),$(NF-2)}'

or perhaps (on Sys V based systems):

#!/bin/sh
/usr/bin/df -k "$1" | tail -1 | awk '{print $3" "$5}'

Note that you may have to replace the command names with full path
names on some systems. Also note the arguments passed into the
script should be quoted inside the script in case they contain
special characters such as spaces or newlines.

By default internal routines for determining the disk capacity and
remaining space will be used.

No default

Example: dfree command = /usr/local/samba/bin/dfree

dgram port (G)

Specifies which ports the server should listen on for NetBIOS
datagram traffic.

Default: dgram port = 138

directory mode

This parameter is a synonym for directory mask.

directory mask (S)

This parameter is the octal modes which are used when converting
DOS modes to UNIX modes when creating UNIX directories.

When a directory is created, the necessary permissions are
calculated according to the mapping from DOS modes to UNIX
permissions, and the resulting UNIX mode is then bit-wise 'AND'ed
with this parameter. This parameter may be thought of as a bit-wise
MASK for the UNIX modes of a directory. Any bit not set here will
be removed from the modes set on a directory when it is created.

The default value of this parameter removes the 'group' and 'other'
write bits from the UNIX mode, allowing only the user who owns the
directory to modify it.

Following this Samba will bit-wise 'OR' the UNIX mode created from
this parameter with the value of the force directory mode
parameter. This parameter is set to 000 by default (i.e. no extra
mode bits are added).

Default: directory mask = 0755

Example: directory mask = 0775

directory security mask (S)

This parameter has been removed for Samba 4.0.0.

No default

disable netbios (G)

Enabling this parameter will disable netbios support in Samba.
Netbios is the only available form of browsing in Windows versions
prior to Windows 2000.

Note
Clients that only support netbios won't be able to see your
samba server when netbios support is disabled.
Default: disable netbios = no

disable spoolss (G)

Enabling this parameter will disable Samba's support for the
SPOOLSS set of MS-RPC's and will yield identical behavior as Samba
2.0.x. Windows NT/2000 clients will downgrade to using Lanman style
printing commands. Windows 9x/ME will be unaffected by the
parameter. However, this will also disable the ability to upload
printer drivers to a Samba server via the Windows NT Add Printer
Wizard or by using the NT printer properties dialog window. It will
also disable the capability of Windows NT/2000 clients to download
print drivers from the Samba host upon demand. Be very careful
about enabling this parameter.

Default: disable spoolss = no

dmapi support (S)

This parameter specifies whether Samba should use DMAPI to
determine whether a file is offline or not. This would typically be
used in conjunction with a hierarchical storage system that
automatically migrates files to tape.

Note that Samba infers the status of a file by examining the events
that a DMAPI application has registered interest in. This heuristic
is satisfactory for a number of hierarchical storage systems, but
there may be system for which it will fail. In this case, Samba may
erroneously report files to be offline.

This parameter is only available if a supported DMAPI
implementation was found at compilation time. It will only be used
if DMAPI is found to enabled on the system at run time.

Default: dmapi support = no

dns forwarder (G)

This option specifies the list of DNS servers that DNS requests
will be forwarded to if they can not be handled by Samba itself.

The DNS forwarder is only used if the internal DNS server in Samba
is used. Port numbers can be appended by separating them from the
address by using a colon (':'). When specifying a port, IPv6
addresses must be enclosed in square brackets ('[' and ']'). IPv6
forwarder addresses with no port specified, don't need the square
brackets, and default to port 53.

Default: dns forwarder =

Example: dns forwarder = 192.168.0.1 192.168.0.2 ::1 [2001:db8::1]
[2001:db8:1:2::1]:54

dns port (G)

Specifies which ports the server should listen on for DNS traffic.

It makes possible to use another DNS server as a front and forward
to Samba.

Warning
Dynamic DNS updates may not be proxied by the front DNS server
when forwarding to Samba. Dynamic DNS update proxying depends
on the features of the other DNS server used as a front.
Default: dns port = 53

dns proxy (G)

Specifies that nmbd(8) when acting as a WINS server and finding
that a NetBIOS name has not been registered, should treat the
NetBIOS name word-for-word as a DNS name and do a lookup with the
DNS server for that name on behalf of the name-querying client.

Note that the maximum length for a NetBIOS name is 15 characters,
so the DNS name (or DNS alias) can likewise only be 15 characters,
maximum.

nmbd spawns a second copy of itself to do the DNS name lookup
requests, as doing a name lookup is a blocking action.

Default: dns proxy = yes

dns update command (G)

This option sets the command that is called when there are DNS
updates. It should update the local machines DNS names using
TSIG-GSS.

Default: dns update command = ${prefix}/sbin/samba_dnsupdate

Example: dns update command = /usr/local/sbin/dnsupdate

dns zone scavenging (G)

When enabled (the default is disabled) unused dynamic dns records
are periodically removed.

Warning
This option should not be enabled for installations created
with versions of samba before 4.9. Doing this will result in
the loss of static DNS entries. This is due to a bug in
previous versions of samba (BUG 12451) which marked dynamic DNS
records as static and static records as dynamic.

Note
If one record for a DNS name is static (non-aging) then no
other record for that DNS name will be scavenged.
Default: dns zone scavenging = no

dns zone transfer clients allow (G)

This option specifies the list of IPs authorized to ask for dns
zone transfer from bind DLZ module.

The IP list is comma and space separated and specified in the same
syntax as used in hosts allow, specifically including IP address,
IP prefixes and IP address masks.

As this is a DNS server option, hostnames are naturally not
permitted.

The default behaviour is to deny any request. A request will be
authorized only if the emitting client is identified in this list,
and not in dns zone transfer clients deny

Default: dns zone transfer clients allow =

Example: dns zone transfer clients allow = 192.168.0.1

dns zone transfer clients deny (G)

This option specifies the list of IPs denied to ask for dns zone
transfer from bind DLZ module.

The IP list is comma and space separated and specified in the same
syntax as used in hosts allow, specifically including IP address,
IP prefixes and IP address masks.

As this is a DNS server option, hostnames are naturally not
permitted.

If a client identified in this list sends a zone transfer request,
it will always be denied, even if they are in dns zone transfer
clients allow. This allows the definition of specific denied
clients within an authorized subnet.

Default: dns zone transfer clients deny =

Example: dns zone transfer clients deny = 192.168.0.1

domain logons (G)

This parameter has been deprecated since Samba 4.13 and support for
NT4-style domain logons(as distinct from the Samba AD DC) will be
removed in a future Samba release.

That is, in the future, the current default of domain logons = no
will be the enforced behaviour.

If set to yes, the Samba server will provide the netlogon service
for Windows 9X network logons for the workgroup it is in. This will
also cause the Samba server to act as a domain controller for NT4
style domain services. For more details on setting up this feature
see the Domain Control chapter of the Samba HOWTO Collection.

Default: domain logons = no

domain master (G)

Tell smbd(8) to enable WAN-wide browse list collation. Setting this
option causes nmbd to claim a special domain specific NetBIOS name
that identifies it as a domain master browser for its given
workgroup. Local master browsers in the same workgroup on
broadcast-isolated subnets will give this nmbd their local browse
lists, and then ask smbd(8) for a complete copy of the browse list
for the whole wide area network. Browser clients will then contact
their local master browser, and will receive the domain-wide browse
list, instead of just the list for their broadcast-isolated subnet.

Note that Windows NT Primary Domain Controllers expect to be able
to claim this workgroup specific special NetBIOS name that
identifies them as domain master browsers for that workgroup by
default (i.e. there is no way to prevent a Windows NT PDC from
attempting to do this). This means that if this parameter is set
and nmbd claims the special name for a workgroup before a Windows
NT PDC is able to do so then cross subnet browsing will behave
strangely and may fail.

If domain logons = yes, then the default behavior is to enable the
domain master parameter. If domain logons is not enabled (the
default setting), then neither will domain master be enabled by
default.

When domain logons = Yes the default setting for this parameter is
Yes, with the result that Samba will be a PDC. If domain master =
No, Samba will function as a BDC. In general, this parameter should
be set to 'No' only on a BDC.

Default: domain master = auto

dont descend (S)

There are certain directories on some systems (e.g., the /proc tree
under Linux) that are either not of interest to clients or are
infinitely deep (recursive). This parameter allows you to specify a
comma-delimited list of directories that the server should always
show as empty.

Note that Samba can be very fussy about the exact format of the
"dont descend" entries. For example you may need ./proc instead of
just /proc. Experimentation is the best policy :-)

Default: dont descend =

Example: dont descend = /proc,/dev

dos charset (G)

DOS SMB clients assume the server has the same charset as they do.
This option specifies which charset Samba should use to talk to DOS
clients.

The default depends on which charsets you have installed. Samba
tries to use charset 850 but falls back to ASCII in case it is not
available. Run testparm(1) to check the default on your system.

No default

dos filemode (S)

The default behavior in Samba is to provide UNIX-like behavior
where only the owner of a file/directory is able to change the
permissions on it. However, this behavior is often confusing to
DOS/Windows users. Enabling this parameter allows a user who has
write access to the file (by whatever means, including an ACL
permission) to modify the permissions (including ACL) on it. Note
that a user belonging to the group owning the file will not be
allowed to change permissions if the group is only granted read
access. Ownership of the file/directory may also be changed. Note
that using the VFS modules acl_xattr or acl_tdb which store native
Windows as meta-data will automatically turn this option on for any
share for which they are loaded, as they require this option to
emulate Windows ACLs correctly.

Default: dos filemode = no

dos filetime resolution (S)

Under the DOS and Windows FAT filesystem, the finest granularity on
time resolution is two seconds. Setting this parameter for a share
causes Samba to round the reported time down to the nearest two
second boundary when a query call that requires one second
resolution is made to smbd(8).

This option is mainly used as a compatibility option for Visual C++
when used against Samba shares. If oplocks are enabled on a share,
Visual C++ uses two different time reading calls to check if a file
has changed since it was last read. One of these calls uses a
one-second granularity, the other uses a two second granularity. As
the two second call rounds any odd second down, then if the file
has a timestamp of an odd number of seconds then the two timestamps
will not match and Visual C++ will keep reporting the file has
changed. Setting this option causes the two timestamps to match,
and Visual C++ is happy.

Default: dos filetime resolution = no

dos filetimes (S)

Under DOS and Windows, if a user can write to a file they can
change the timestamp on it. Under POSIX semantics, only the owner
of the file or root may change the timestamp. By default, Samba
emulates the DOS semantics and allows one to change the timestamp
on a file if the user smbd is acting on behalf has write
permissions. Due to changes in Microsoft Office 2000 and beyond,
the default for this parameter has been changed from "no" to "yes"
in Samba 3.0.14 and above. Microsoft Excel will display dialog box
warnings about the file being changed by another user if this
parameter is not set to "yes" and files are being shared between
users.

Default: dos filetimes = yes

dsdb event notification (G)

When enabled, this option causes Samba (acting as an Active
Directory Domain Controller) to stream Samba database events across
the internal message bus. Scripts built using Samba's python
bindings can listen to these events by registering as the service
dsdb_event.

This is not needed for the audit logging described in log level.

The Samba database events are also logged via the normal logging
methods when the log level is set appropriately, say to
dsdb_json_audit:5.

Default: dsdb event notification = no

dsdb group change notification (G)

When enabled, this option causes Samba (acting as an Active
Directory Domain Controller) to stream group membership change
events across the internal message bus. Scripts built using Samba's
python bindings can listen to these events by registering as the
service dsdb_group_event.

This is not needed for the audit logging described in log level.

The Samba database events are also logged via the normal logging
methods when the log level is set appropriately, say to
dsdb_group_json_audit:5.

Default: dsdb group change notification = no

dsdb password event notification (G)

When enabled, this option causes Samba (acting as an Active
Directory Domain Controller) to stream password change and reset
events across the internal message bus. Scripts built using Samba's
python bindings can listen to these events by registering as the
service password_event.

This is not needed for the audit logging described in log level.

The Samba database events are also logged via the normal logging
methods when the log level is set appropriately, say to
dsdb_password_json_audit:5.

Default: dsdb password event notification = no

durable handles (S)

This boolean parameter controls whether Samba can grant SMB2
durable file handles on a share.

Note that durable handles are only enabled if kernel oplocks = no,
kernel share modes = no, and posix locking = no, i.e. if the share
is configured for CIFS/SMB2 only access, not supporting
interoperability features with local UNIX processes or NFS
operations.

Also note that, for the time being, durability is not granted for a
handle that has the delete on close flag set.

Default: durable handles = yes

ea support (S)

This boolean parameter controls whether smbd(8) will allow clients
to attempt to access extended attributes on a share. In order to
enable this parameter on a setup with default VFS modules:

o Samba must have been built with extended attributes
support.

o The underlying filesystem exposed by the share must
support extended attributes (e.g. the getfattr(1) /
setfattr(1) utilities must work).

o Access to extended user attributes must be allowed by
the underlying filesystem (e.g. when mounted with a
system-dependent option like user_xattr on Linux).

This option exposes the "user" attribute namespace from the
underlying filesystem to clients. In order to match Windows
conventions, the namespace prefix ("user.") is stripped from the
attribute name on the client side. The handling of further
attribute namespaces (like "security", "system", or "trusted") is
not affected by this option.

Note that the SMB protocol allows setting attributes whose value is
64K bytes long, and that on NTFS, the maximum storage space for
extended attributes per file is 64K. On some filesystem the limits
may be lower. Filesystems with too limited EA space may experience
unexpected weird effects. The default has changed to yes in Samba
release 4.9.0 and above to allow better Windows fileserver
compatibility in a default install.

Default: ea support = yes

elasticsearch:address (S)

Specifies the name of the Elasticsearch server to use for Spotlight
queries when using the Elasticsearch backend.

Default: elasticsearch:address = localhost

Example: elasticsearch:address = needle.haystack.samba.org

elasticsearch:ignore unknown attribute (G)

Ignore unknown Spotlight attributes in search queries. An example
query using the unsupported attribute "kMDItemTopic" would be
kMDItemTopic=="hotstuff". By default any query using such a type
would completely fail. By enabling this option, if the type match
is a subexpression of a larger expression, then this subexpression
is just ignored.

Default: elasticsearch:ignore unknown attribute = no

Example: elasticsearch:ignore unknown attribute = yes

elasticsearch:ignore unknown type (G)

Ignore unknown Spotlight types in search queries. An example query
using the unsupported type "public.calendar-event" would be
kMDItemContentType=="public.calendar-event". By default any query
using such a type would completely fail. By enabling this option,
if the type match is a subexpression of a larger expression, then
this subexpression is just ignored.

Default: elasticsearch:ignore unknown type = no

Example: elasticsearch:ignore unknown type = yes

elasticsearch:index (S)

Specifies the name of the Elasticsearch index to use for Spotlight
queries when using the Elasticsearch backend. The default value of
"_all" is a special Elasticsearch value that performs the search
operation on all indices.

Default: elasticsearch:index = _all

Example: elasticsearch:index = spotlight

elasticsearch:mappings (G)

Path to a file specifying metadata attribute mappings in JSON
format. Use by the Elasticsearch backend of the Spotlight RPC
service.

Default: elasticsearch:mappings =
${prefix}/var/samba/elasticsearch_mappings.json

Example: elasticsearch:mappings = /usr/share/foo/mymappings.json

elasticsearch:max results (S)

Path to a file specifying metadata attribute mappings in JSON
format. Used by the Elasticsearch backend of the Spotlight RPC
service. A value of 0 means no limit.

Default: elasticsearch:max results = 100

Example: elasticsearch:max results = 10

elasticsearch:port (S)

Specifies the TCP port of the Elasticsearch server to use for
Spotlight queries when using the Elasticsearch backend.

Default: elasticsearch:port = 9200

Example: elasticsearch:port = 9201

elasticsearch:use tls (S)

Specifies whether to use HTTPS when talking to the Elasticsearch
server used for Spotlight queries when using the Elasticsearch
backend.

Default: elasticsearch:use tls = no

Example: elasticsearch:use tls = yes

enable asu support (G)

Hosts running the "Advanced Server for Unix (ASU)" product require
some special accommodations such as creating a builtin [ADMIN$]
share that only supports IPC connections. The has been the default
behavior in smbd for many years. However, certain Microsoft
applications such as the Print Migrator tool require that the
remote server support an [ADMIN$] file share. Disabling this
parameter allows for creating an [ADMIN$] file share in smb.conf.

Default: enable asu support = no

enable core files (G)

This parameter specifies whether core dumps should be written on
internal exits. Normally set to yes. You should never need to
change this.

Default: enable core files = yes

Example: enable core files = no

enable privileges (G)

This deprecated parameter controls whether or not smbd will honor
privileges assigned to specific SIDs via either net rpc rights or
one of the Windows user and group manager tools. This parameter is
enabled by default. It can be disabled to prevent members of the
Domain Admins group from being able to assign privileges to users
or groups which can then result in certain smbd operations running
as root that would normally run under the context of the connected
user.

An example of how privileges can be used is to assign the right to
join clients to a Samba controlled domain without providing root
access to the server via smbd.

Please read the extended description provided in the Samba HOWTO
documentation.

Default: enable privileges = yes

enable spoolss (G)

Inverted synonym for disable spoolss.

Default: enable spoolss = yes

encrypt passwords (G)

This parameter has been deprecated since Samba 4.11 and support for
plaintext (as distinct from NTLM, NTLMv2 or Kerberos
authentication) will be removed in a future Samba release.

That is, in the future, the current default of encrypt passwords =
yes will be the enforced behaviour.

This boolean controls whether encrypted passwords will be
negotiated with the client. Note that Windows NT 4.0 SP3 and above
and also Windows 98 will by default expect encrypted passwords
unless a registry entry is changed. To use encrypted passwords in
Samba see the chapter "User Database" in the Samba HOWTO
Collection.

MS Windows clients that expect Microsoft encrypted passwords and
that do not have plain text password support enabled will be able
to connect only to a Samba server that has encrypted password
support enabled and for which the user accounts have a valid
encrypted password. Refer to the smbpasswd command man page for
information regarding the creation of encrypted passwords for user
accounts.

The use of plain text passwords is NOT advised as support for this
feature is no longer maintained in Microsoft Windows products. If
you want to use plain text passwords you must set this parameter to
no.

In order for encrypted passwords to work correctly smbd(8) must
either have access to a local smbpasswd(5) file (see the
smbpasswd(8) program for information on how to set up and maintain
this file), or set the security = [domain|ads] parameter which
causes smbd to authenticate against another server.

Default: encrypt passwords = yes

enhanced browsing (G)

This option enables a couple of enhancements to cross-subnet browse
propagation that have been added in Samba but which are not
standard in Microsoft implementations.

The first enhancement to browse propagation consists of a regular
wildcard query to a Samba WINS server for all Domain Master
Browsers, followed by a browse synchronization with each of the
returned DMBs. The second enhancement consists of a regular
randomised browse synchronization with all currently known DMBs.

You may wish to disable this option if you have a problem with
empty workgroups not disappearing from browse lists. Due to the
restrictions of the browse protocols, these enhancements can cause
a empty workgroup to stay around forever which can be annoying.

In general you should leave this option enabled as it makes
cross-subnet browse propagation much more reliable.

Default: enhanced browsing = yes

enumports command (G)

The concept of a "port" is fairly foreign to UNIX hosts. Under
Windows NT/2000 print servers, a port is associated with a port
monitor and generally takes the form of a local port (i.e. LPT1:,
COM1:, FILE:) or a remote port (i.e. LPD Port Monitor, etc...). By
default, Samba has only one port defined--"Samba Printer Port".
Under Windows NT/2000, all printers must have a valid port name. If
you wish to have a list of ports displayed (smbd does not use a
port name for anything) other than the default "Samba Printer
Port", you can define enumports command to point to a program which
should generate a list of ports, one per line, to standard output.
This listing will then be used in response to the level 1 and 2
EnumPorts() RPC.

Default: enumports command =

Example: enumports command = /usr/bin/listports

eventlog list (G)

This option defines a list of log names that Samba will report to
the Microsoft EventViewer utility. The listed eventlogs will be
associated with tdb file on disk in the $(statedir)/eventlog.

The administrator must use an external process to parse the normal
Unix logs such as /var/log/messages and write then entries to the
eventlog tdb files. Refer to the eventlogadm(8) utility for how to
write eventlog entries.

Default: eventlog list =

Example: eventlog list = Security Application Syslog Apache

fake directory create times (S)

NTFS and Windows VFAT file systems keep a create time for all files
and directories. This is not the same as the ctime - status change
time - that Unix keeps, so Samba by default reports the earliest of
the various times Unix does keep. Setting this parameter for a
share causes Samba to always report midnight 1-1-1980 as the create
time for directories.

This option is mainly used as a compatibility option for Visual C++
when used against Samba shares. Visual C++ generated makefiles have
the object directory as a dependency for each object file, and a
make rule to create the directory. Also, when NMAKE compares
timestamps it uses the creation time when examining a directory.
Thus the object directory will be created if it does not exist, but
once it does exist it will always have an earlier timestamp than
the object files it contains.

However, Unix time semantics mean that the create time reported by
Samba will be updated whenever a file is created or deleted in the
directory. NMAKE finds all object files in the object directory.
The timestamp of the last one built is then compared to the
timestamp of the object directory. If the directory's timestamp if
newer, then all object files will be rebuilt. Enabling this option
ensures directories always predate their contents and an NMAKE
build will proceed as expected.

Default: fake directory create times = no

fake oplocks (S)

Oplocks are the way that SMB clients get permission from a server
to locally cache file operations. If a server grants an oplock
(opportunistic lock) then the client is free to assume that it is
the only one accessing the file and it will aggressively cache file
data. With some oplock types the client may even cache file
open/close operations. This can give enormous performance benefits.

When you set fake oplocks = yes, smbd(8) will always grant oplock
requests no matter how many clients are using the file.

It is generally much better to use the real oplocks support rather
than this parameter.

If you enable this option on all read-only shares or shares that
you know will only be accessed from one client at a time such as
physically read-only media like CDROMs, you will see a big
performance improvement on many operations. If you enable this
option on shares where multiple clients may be accessing the files
read-write at the same time you can get data corruption. Use this
option carefully!

Default: fake oplocks = no

follow symlinks (S)

This parameter allows the Samba administrator to stop smbd(8) from
following symbolic links in a particular share. Setting this
parameter to no prevents any file or directory that is a symbolic
link from being followed (the user will get an error). This option
is very useful to stop users from adding a symbolic link to
/etc/passwd in their home directory for instance. However it will
slow filename lookups down slightly.

This option is enabled (i.e. smbd will follow symbolic links) by
default.

Default: follow symlinks = yes

smbd force process locks (S)

This boolean option tells smbd whether to forcefully disable the
use of Open File Description locks on Linux.

This option should not be changed from the default unless you know
what you're doing.

Default: smbd force process locks = no

force create mode (S)

This parameter specifies a set of UNIX mode bit permissions that
will always be set on a file created by Samba. This is done by
bitwise 'OR'ing these bits onto the mode bits of a file that is
being created. The default for this parameter is (in octal) 000.
The modes in this parameter are bitwise 'OR'ed onto the file mode
after the mask set in the create mask parameter is applied.

The example below would force all newly created files to have read
and execute permissions set for 'group' and 'other' as well as the
read/write/execute bits set for the 'user'.

Default: force create mode = 0000

Example: force create mode = 0755

force directory mode (S)

This parameter specifies a set of UNIX mode bit permissions that
will always be set on a directory created by Samba. This is done by
bitwise 'OR'ing these bits onto the mode bits of a directory that
is being created. The default for this parameter is (in octal) 0000
which will not add any extra permission bits to a created
directory. This operation is done after the mode mask in the
parameter directory mask is applied.

The example below would force all created directories to have read
and execute permissions set for 'group' and 'other' as well as the
read/write/execute bits set for the 'user'.

Default: force directory mode = 0000

Example: force directory mode = 0755

force directory security mode (S)

This parameter has been removed for Samba 4.0.0.

No default

group

This parameter is a synonym for force group.

force group (S)

This specifies a UNIX group name that will be assigned as the
default primary group for all users connecting to this service.
This is useful for sharing files by ensuring that all access to
files on service will use the named group for their permissions
checking. Thus, by assigning permissions for this group to the
files and directories within this service the Samba administrator
can restrict or allow sharing of these files.

In Samba 2.0.5 and above this parameter has extended functionality
in the following way. If the group name listed here has a '+'
character prepended to it then the current user accessing the share
only has the primary group default assigned to this group if they
are already assigned as a member of that group. This allows an
administrator to decide that only users who are already in a
particular group will create files with group ownership set to that
group. This gives a finer granularity of ownership assignment. For
example, the setting force group = +sys means that only users who
are already in group sys will have their default primary group
assigned to sys when accessing this Samba share. All other users
will retain their ordinary primary group.

If the force user parameter is also set the group specified in
force group will override the primary group set in force user.

Default: force group =

Example: force group = agroup

force printername (S)

When printing from Windows NT (or later), each printer in smb.conf
has two associated names which can be used by the client. The first
is the sharename (or shortname) defined in smb.conf. This is the
only printername available for use by Windows 9x clients. The
second name associated with a printer can be seen when browsing to
the "Printers" (or "Printers and Faxes") folder on the Samba
server. This is referred to simply as the printername (not to be
confused with the printer name option).

When assigning a new driver to a printer on a remote Windows
compatible print server such as Samba, the Windows client will
rename the printer to match the driver name just uploaded. This can
result in confusion for users when multiple printers are bound to
the same driver. To prevent Samba from allowing the printer's
printername to differ from the sharename defined in smb.conf, set
force printername = yes.

Be aware that enabling this parameter may affect migrating printers
from a Windows server to Samba since Windows has no way to force
the sharename and printername to match.

It is recommended that this parameter's value not be changed once
the printer is in use by clients as this could cause a user not be
able to delete printer connections from their local Printers
folder.

Default: force printername = no

force security mode (S)

This parameter has been removed for Samba 4.0.0.

No default

force unknown acl user (S)

If this parameter is set, a Windows NT ACL that contains an unknown
SID (security descriptor, or representation of a user or group id)
as the owner or group owner of the file will be silently mapped
into the current UNIX uid or gid of the currently connected user.

This is designed to allow Windows NT clients to copy files and
folders containing ACLs that were created locally on the client
machine and contain users local to that machine only (no domain
users) to be copied to a Samba server (usually with XCOPY /O) and
have the unknown userid and groupid of the file owner map to the
current connected user. This can only be fixed correctly when
winbindd allows arbitrary mapping from any Windows NT SID to a UNIX
uid or gid.

Try using this parameter when XCOPY /O gives an ACCESS_DENIED
error.

Default: force unknown acl user = no

force user (S)

This specifies a UNIX user name that will be assigned as the
default user for all users connecting to this service. This is
useful for sharing files. You should also use it carefully as using
it incorrectly can cause security problems.

This user name only gets used once a connection is established.
Thus clients still need to connect as a valid user and supply a
valid password. Once connected, all file operations will be
performed as the "forced user", no matter what username the client
connected as. This can be very useful.

In Samba 2.0.5 and above this parameter also causes the primary
group of the forced user to be used as the primary group for all
file activity. Prior to 2.0.5 the primary group was left as the
primary group of the connecting user (this was a bug).

Default: force user =

Example: force user = auser

fss: prune stale (G)

When enabled, Samba's File Server Remote VSS Protocol (FSRVP)
server checks all FSRVP initiated snapshots on startup, and removes
any corresponding state (including share definitions) for
nonexistent snapshot paths.

Default: fss: prune stale = no

Example: fss: prune stale = yes

fss: sequence timeout (G)

The File Server Remote VSS Protocol (FSRVP) server includes a
message sequence timer to ensure cleanup on unexpected client
disconnect. This parameter overrides the default timeout between
FSRVP operations. FSRVP timeouts can be completely disabled via a
value of 0.

Default: fss: sequence timeout = 180 or 1800, depending on
operation

Example: fss: sequence timeout = 0

fstype (S)

This parameter allows the administrator to configure the string
that specifies the type of filesystem a share is using that is
reported by smbd(8) when a client queries the filesystem type for a
share. The default type is NTFS for compatibility with Windows NT
but this can be changed to other strings such as Samba or FAT if
required.

Default: fstype = NTFS

Example: fstype = Samba

get quota command (G)

The get quota command should only be used whenever there is no
operating system API available from the OS that samba can use.

This option is only available Samba was compiled with quotas
support.

This parameter should specify the path to a script that queries the
quota information for the specified user/group for the partition
that the specified directory is on.

Such a script is being given 3 arguments:

o directory

o type of query

o uid of user or gid of group

The directory is actually mostly just "." - It needs to be treated
relatively to the current working directory that the script can
also query.

The type of query can be one of:

o 1 - user quotas

o 2 - user default quotas (uid = -1)

o 3 - group quotas

o 4 - group default quotas (gid = -1)

This script should print one line as output with spaces between the
columns. The printed columns should be:

o 1 - quota flags (0 = no quotas, 1 = quotas enabled, 2 =
quotas enabled and enforced)

o 2 - number of currently used blocks

o 3 - the softlimit number of blocks

o 4 - the hardlimit number of blocks

o 5 - currently used number of inodes

o 6 - the softlimit number of inodes

o 7 - the hardlimit number of inodes

o 8 (optional) - the number of bytes in a block(default is
1024)

Default: get quota command =

Example: get quota command = /usr/local/sbin/query_quota

getwd cache (G)

This is a tuning option. When this is enabled a caching algorithm
will be used to reduce the time taken for getwd() calls. This can
have a significant impact on performance, especially when the wide
links parameter is set to no.

Default: getwd cache = yes

gpo update command (G)

This option sets the command that is called to apply GPO policies.
The samba-gpupdate script applies System Access and Kerberos
Policies to the KDC. System Access policies set minPwdAge,
maxPwdAge, minPwdLength, and pwdProperties in the samdb. Kerberos
Policies set kdc:service ticket lifetime, kdc:user ticket lifetime,
and kdc:renewal lifetime in smb.conf.

Default: gpo update command = ${prefix}/sbin/samba-gpupdate

Example: gpo update command = /usr/local/sbin/gpoupdate

guest account (G)

This is a username which will be used for access to services which
are specified as guest ok (see below). Whatever privileges this
user has will be available to any client connecting to the guest
service. This user must exist in the password file, but does not
require a valid login. The user account "ftp" is often a good
choice for this parameter.

On some systems the default guest account "nobody" may not be able
to print. Use another account in this case. You should test this by
trying to log in as your guest user (perhaps by using the su -
command) and trying to print using the system print command such as
lpr(1) or lp(1).

This parameter does not accept % macros, because many parts of the
system require this value to be constant for correct operation.

Default: guest account = nobody # default can be changed at
compile-time

Example: guest account = ftp

public

This parameter is a synonym for guest ok.

guest ok (S)

If this parameter is yes for a service, then no password is
required to connect to the service. Privileges will be those of the
guest account.

This parameter nullifies the benefits of setting restrict anonymous
= 2

See the section below on security for more information about this
option.

Default: guest ok = no

only guest

This parameter is a synonym for guest only.

guest only (S)

If this parameter is yes for a service, then only guest connections
to the service are permitted. This parameter will have no effect if
guest ok is not set for the service.

See the section below on security for more information about this
option.

Default: guest only = no

hide dot files (S)

This is a boolean parameter that controls whether files starting
with a dot appear as hidden files.

Default: hide dot files = yes

hide files (S)

This is a list of files or directories that are not visible but are
accessible. The DOS 'hidden' attribute is applied to any files or
directories that match.

Each entry in the list must be separated by a '/', which allows
spaces to be included in the entry. '*' and '?' can be used to
specify multiple files or directories as in DOS wildcards.

Each entry must be a Unix path, not a DOS path and must not include
the Unix directory separator '/'.

Note that the case sensitivity option is applicable in hiding
files.

Setting this parameter will affect the performance of Samba, as it
will be forced to check all files and directories for a match as
they are scanned.

The example shown above is based on files that the Macintosh SMB
client (DAVE) available from Thursby creates for internal use, and
also still hides all files beginning with a dot.

An example of us of this parameter is:

hide files = /.*/DesktopFolderDB/TrashFor%m/resource.frk/

Default: hide files = # no file are hidden

hide new files timeout (S)

Setting this parameter to something but 0 hides files that have
been modified less than N seconds ago.

It can be used for ingest/process queue style workloads. A
processing application should only see files that are definitely
finished. As many applications do not have proper external workflow
control, this can be a way to make sure processing does not
interfere with file ingest.

Default: hide new files timeout = 0

hide special files (S)

This parameter prevents clients from seeing special files such as
sockets, devices and fifo's in directory listings.

Default: hide special files = no

hide unreadable (S)

This parameter prevents clients from seeing the existence of files
that cannot be read. Defaults to off.

Please note that enabling this can slow down listing large
directories significantly. Samba has to evaluate the ACLs of all
directory members, which can be a lot of effort.

Default: hide unreadable = no

hide unwriteable files (S)

This parameter prevents clients from seeing the existence of files
that cannot be written to. Defaults to off. Note that unwriteable
directories are shown as usual.

Please note that enabling this can slow down listing large
directories significantly. Samba has to evaluate the ACLs of all
directory members, which can be a lot of effort.

Default: hide unwriteable files = no

honor change notify privilege (S)

This option can be used to make use of the change notify privilege.
By default notify results are not checked against the file system
permissions.

If "honor change notify privilege" is enabled, a user will only
receive notify results, if he has change notify privilege or
sufficient file system permissions. If a user has the change notify
privilege, he will receive all requested notify results, even if
the user does not have the permissions on the file system.

Default: honor change notify privilege = no

host msdfs (G)

If set to yes, Samba will act as a Dfs server, and allow Dfs-aware
clients to browse Dfs trees hosted on the server.

See also the msdfs root share level parameter. For more information
on setting up a Dfs tree on Samba, refer to the MSFDS chapter in
the book Samba3-HOWTO.

Default: host msdfs = yes

hostname lookups (G)

Specifies whether samba should use (expensive) hostname lookups or
use the ip addresses instead. An example place where hostname
lookups are currently used is when checking the hosts deny and
hosts allow.

Default: hostname lookups = no

Example: hostname lookups = yes

allow hosts

This parameter is a synonym for hosts allow.

hosts allow (S)

A synonym for this parameter is allow hosts.

This parameter is a comma, space, or tab delimited set of hosts
which are permitted to access a service.

If specified in the [global] section then it will apply to all
services, regardless of whether the individual service has a
different setting.

You can specify the hosts by name or IP number. For example, you
could restrict access to only the hosts on a Class C subnet with
something like allow hosts = 150.203.5.. The full syntax of the
list is described in the man page hosts_access(5). Note that this
man page may not be present on your system, so a brief description
will be given here also.

Note that the localhost address 127.0.0.1 will always be allowed
access unless specifically denied by a hosts deny option.

You can also specify hosts by network/netmask pairs and by netgroup
names if your system supports netgroups. The EXCEPT keyword can
also be used to limit a wildcard list. The following examples may
provide some help:

Example 1: allow all IPs in 150.203.*.*; except one

hosts allow = 150.203. EXCEPT 150.203.6.66

Example 2: allow hosts that match the given network/netmask

hosts allow = 150.203.15.0/255.255.255.0

Example 3: allow a couple of hosts

hosts allow = lapland, arvidsjaur

Example 4: allow only hosts in NIS netgroup "foonet", but deny
access from one particular host

hosts allow = @foonet

hosts deny = pirate

Note
Note that access still requires suitable user-level passwords.
See testparm(1) for a way of testing your host access to see if it
does what you expect.

Default: hosts allow = # none (i.e., all hosts permitted access)

Example: hosts allow = 150.203.5. myhost.mynet.edu.au

deny hosts

This parameter is a synonym for hosts deny.

hosts deny (S)

The opposite of hosts allow - hosts listed here are NOT permitted
access to services unless the specific services have their own
lists to override this one. Where the lists conflict, the allow
list takes precedence.

In the event that it is necessary to deny all by default, use the
keyword ALL (or the netmask 0.0.0.0/0) and then explicitly specify
to the hosts allow = hosts allow parameter those hosts that should
be permitted access.

Default: hosts deny = # none (i.e., no hosts specifically
excluded)

Example: hosts deny = 150.203.4. badhost.mynet.edu.au

idmap backend (G)

The idmap backend provides a plugin interface for Winbind to use
varying backends to store SID/uid/gid mapping tables.

This option specifies the default backend that is used when no
special configuration set, but it is now deprecated in favour of
the new spelling idmap config * : backend.

Default: idmap backend = tdb

idmap cache time (G)

This parameter specifies the number of seconds that Winbind's idmap
interface will cache positive SID/uid/gid query results. By
default, Samba will cache these results for one week.

Default: idmap cache time = 604800

idmap config DOMAIN : OPTION (G)

ID mapping in Samba is the mapping between Windows SIDs and Unix
user and group IDs. This is performed by Winbindd with a
configurable plugin interface. Samba's ID mapping is configured by
options starting with the idmap config prefix. An idmap option
consists of the idmap config prefix, followed by a domain name or
the asterisk character (*), a colon, and the name of an idmap
setting for the chosen domain.

The idmap configuration is hence divided into groups, one group for
each domain to be configured, and one group with the asterisk
instead of a proper domain name, which specifies the default
configuration that is used to catch all domains that do not have an
explicit idmap configuration of their own.

There are three general options available:

backend = backend_name
This specifies the name of the idmap plugin to use as the
SID/uid/gid backend for this domain. The standard backends are
tdb (idmap_tdb(8)), tdb2 (idmap_tdb2(8)), ldap (idmap_ldap(8)),
rid (idmap_rid(8)), hash (idmap_hash(8)), autorid
(idmap_autorid(8)), ad (idmap_ad(8)) and nss (idmap_nss(8)).
The corresponding manual pages contain the details, but here is
a summary.

The first three of these create mappings of their own using
internal unixid counters and store the mappings in a database.
These are suitable for use in the default idmap configuration.
The rid and hash backends use a pure algorithmic calculation to
determine the unixid for a SID. The autorid module is a mixture
of the tdb and rid backend. It creates ranges for each domain
encountered and then uses the rid algorithm for each of these
automatically configured domains individually. The ad backend
uses unix ids stored in Active Directory via the standard
schema extensions. The nss backend reverses the standard
winbindd setup and gets the unix ids via names from nsswitch
which can be useful in an ldap setup.

range = low - high
Defines the available matching uid and gid range for which the
backend is authoritative. For allocating backends, this also
defines the start and the end of the range for allocating new
unique IDs.

winbind uses this parameter to find the backend that is
authoritative for a unix ID to SID mapping, so it must be set
for each individually configured domain and for the default
configuration. The configured ranges must be mutually disjoint.

Note that the low value interacts with the min domain uid
option!

read only = yes|no
This option can be used to turn the writing backends tdb, tdb2,
and ldap into read only mode. This can be useful e.g. in cases
where a pre-filled database exists that should not be extended
automatically.

The following example illustrates how to configure the idmap_ad(8)
backend for the CORP domain and the idmap_tdb(8) backend for all
other domains. This configuration assumes that the admin of CORP
assigns unix ids below 1000000 via the SFU extensions, and winbind
is supposed to use the next million entries for its own mappings
from trusted domains and for local groups for example.

idmap config * : backend = tdb
idmap config * : range = 1000000-1999999

idmap config CORP : backend = ad
idmap config CORP : range = 1000-999999

No default

winbind gid

This parameter is a synonym for idmap gid.

idmap gid (G)

The idmap gid parameter specifies the range of group ids for the
default idmap configuration. It is now deprecated in favour of
idmap config * : range.

See the idmap config option.

Default: idmap gid =

Example: idmap gid = 10000-20000

idmap negative cache time (G)

This parameter specifies the number of seconds that Winbind's idmap
interface will cache negative SID/uid/gid query results.

Default: idmap negative cache time = 120

winbind uid

This parameter is a synonym for idmap uid.

idmap uid (G)

The idmap uid parameter specifies the range of user ids for the
default idmap configuration. It is now deprecated in favour of
idmap config * : range.

See the idmap config option.

Default: idmap uid =

Example: idmap uid = 10000-20000

include (S)

This allows you to include one config file inside another. The file
is included literally, as though typed in place.

It takes the standard substitutions, except %u, %P and %S.

The parameter include = registry has a special meaning: It does not
include a file named registry from the current working directory,
but instead reads the global configuration options from the
registry. See the section on registry-based configuration for
details. Note that this option automatically activates registry
shares.

Default: include =

Example: include = /usr/local/samba/lib/admin_smb.conf

include system krb5 conf (G)

Setting this parameter to no will prevent winbind to include the
system /etc/krb5.conf file into the krb5.conf file it creates. See
also create krb5 conf. This option only applies to Samba built with
MIT Kerberos.

Default: include system krb5 conf = yes

inherit acls (S)

This parameter is only relevant for filesystems that do not support
standardized NFS4 ACLs but only a POSIX draft ACL implementation
and which implements default ACLs like most filesystems on Linux.
It can be used to ensure that if default ACLs exist on parent
directories, they are always honored when creating a new file or
subdirectory in these parent directories. The default behavior is
to use the unix mode specified when creating the directory.
Enabling this option sets the unix mode to 0777, thus guaranteeing
that the default directory ACLs are propagated. Note that using the
VFS modules acl_xattr or acl_tdb which store native Windows as
meta-data will automatically turn this option on for any share for
which they are loaded, as they require this option to emulate
Windows ACLs correctly.

Default: inherit acls = no

inherit owner (S)

The ownership of new files and directories is normally governed by
effective uid of the connected user. This option allows the Samba
administrator to specify that the ownership for new files and
directories should be controlled by the ownership of the parent
directory.

Valid options are:

o no - Both the Windows (SID) owner and the UNIX (uid)
owner of the file are governed by the identity of the
user that created the file.

o windows and unix - The Windows (SID) owner and the UNIX
(uid) owner of new files and directories are set to the
respective owner of the parent directory.

o yes - a synonym for windows and unix.

o unix only - Only the UNIX owner is set to the UNIX owner
of the parent directory.

Common scenarios where this behavior is useful is in implementing
drop-boxes, where users can create and edit files but not delete
them and ensuring that newly created files in a user's roaming
profile directory are actually owned by the user.

The unix only option effectively breaks the tie between the Windows
owner of a file and the UNIX owner. As a logical consequence, in
this mode, setting the Windows owner of a file does not modify the
UNIX owner. Using this mode should typically be combined with a
backing store that can emulate the full NT ACL model without
affecting the POSIX permissions, such as the acl_xattr VFS module,
coupled with acl_xattr:ignore system acls = yes. This can be used
to emulate folder quotas, when files are exposed only via SMB
(without UNIX extensions). The UNIX owner of a directory is locally
set and inherited by all subdirectories and files, and they all
consume the same quota.

Default: inherit owner = no

inherit permissions (S)

The permissions on new files and directories are normally governed
by create mask, directory mask, force create mode and force
directory mode but the boolean inherit permissions parameter
overrides this.

New directories inherit the mode of the parent directory, including
bits such as setgid.

New files inherit their read/write bits from the parent directory.
Their execute bits continue to be determined by map archive, map
hidden and map system as usual.

Note that the setuid bit is never set via inheritance (the code
explicitly prohibits this).

This can be particularly useful on large systems with many users,
perhaps several thousand, to allow a single [homes] share to be
used flexibly by each user.

Default: inherit permissions = no

init logon delay (G)

This parameter specifies a delay in milliseconds for the hosts
configured for delayed initial samlogon with init logon delayed
hosts.

Default: init logon delay = 100

init logon delayed hosts (G)

This parameter takes a list of host names, addresses or networks
for which the initial samlogon reply should be delayed (so other
DCs get preferred by XP workstations if there are any).

The length of the delay can be specified with the init logon delay
parameter.

Default: init logon delayed hosts =

Example: init logon delayed hosts = 150.203.5. myhost.mynet.de

interfaces (G)

This option allows you to override the default network interfaces
list that Samba will use for browsing, name registration and other
NetBIOS over TCP/IP (NBT) traffic. By default Samba will query the
kernel for the list of all active interfaces and use any interfaces
except 127.0.0.1 that are broadcast capable.

The option takes a list of interface strings. Each string can be in
any of the following forms:

o a network interface name (such as eth0). This may
include shell-like wildcards so eth* will match any
interface starting with the substring "eth"

o an IP address. In this case the netmask is determined
from the list of interfaces obtained from the kernel

o an IP/mask pair.

o a broadcast/mask pair.

The "mask" parameters can either be a bit length (such as 24 for a
C class network) or a full netmask in dotted decimal form.

The "IP" parameters above can either be a full dotted decimal IP
address or a hostname which will be looked up via the OS's normal
hostname resolution mechanisms.

By default Samba enables all active interfaces that are broadcast
capable except the loopback adaptor (IP address 127.0.0.1).

In order to support SMB3 multi-channel configurations, smbd
understands some extra parameters which can be appended after the
actual interface with this extended syntax (note that the quoting
is important in order to handle the ; and , characters):

"interface[;key1=value1[,key2=value2[...]]]"

Known keys are speed, capability, and if_index. Speed is specified
in bits per second. Known capabilities are RSS and RDMA. The
if_index should be used with care: the values must not coincide
with indexes used by the kernel. Note that these options are mainly
intended for testing and development rather than for production
use. At least on Linux systems, these values should be
auto-detected, but the settings can serve as last a resort when
autodetection is not working or is not available. The specified
values overwrite the auto-detected values.

The first two example below configures three network interfaces
corresponding to the eth0 device and IP addresses 192.168.2.10 and
192.168.3.10. The netmasks of the latter two interfaces would be
set to 255.255.255.0.

The other examples show how per interface extra parameters can be
specified. Notice the possible usage of "," and ";", which makes
the double quoting necessary.

Default: interfaces =

Example: interfaces = eth0 192.168.2.10/24
192.168.3.10/255.255.255.0

Example: interfaces = eth0, 192.168.2.10/24;
192.168.3.10/255.255.255.0

Example: interfaces =
"eth0;if_index=65,speed=1000000000,capability=RSS"

Example: interfaces = "lo;speed=1000000000" "eth0;capability=RSS"

Example: interfaces = "lo;speed=1000000000" , "eth0;capability=RSS"

Example: interfaces = "eth0;capability=RSS" ,
"rdma1;capability=RDMA" ; "rdma2;capability=RSS,capability=RDMA"

invalid users (S)

This is a list of users that should not be allowed to login to this
service. This is really a paranoid check to absolutely ensure an
improper setting does not breach your security.

A name starting with a '@' is interpreted as an NIS netgroup first
(if your system supports NIS), and then as a UNIX group if the name
was not found in the NIS netgroup database.

A name starting with '+' is interpreted only by looking in the UNIX
group database via the NSS getgrnam() interface. A name starting
with '&' is interpreted only by looking in the NIS netgroup
database (this requires NIS to be working on your system). The
characters '+' and '&' may be used at the start of the name in
either order so the value +_group means check the UNIX group
database, followed by the NIS netgroup database, and the value
_+group means check the NIS netgroup database, followed by the UNIX
group database (the same as the '@' prefix).

The current servicename is substituted for %S. This is useful in
the [homes] section.

Default: invalid users = # no invalid users

Example: invalid users = root fred admin @wheel

iprint server (G)

This parameter is only applicable if printing is set to iprint.

If set, this option overrides the ServerName option in the CUPS
client.conf. This is necessary if you have virtual samba servers
that connect to different CUPS daemons.

Default: iprint server = ""

Example: iprint server = MYCUPSSERVER

kdc default domain supported enctypes (G)

Set the default value of msDS-SupportedEncryptionTypes for service
accounts in Active Directory that are missing this value or where
msDS-SupportedEncryptionTypes is set to 0.

This allows Samba administrators to match the configuration
flexibility provided by the
HKEY_LOCAL_MACHINE\System\CurrentControlSet\services\KDC\DefaultDomainSupportedEncTypes
Registry Value on Windows.

Unlike the Windows registry key (which only takes an base-10
number), in Samba this may also be expressed in hexadecimal or as a
list of Kerberos encryption type names.

Specified values are ORed together bitwise, and those currently
supported consist of:

o arcfour-hmac-md5, rc4-hmac, 0x4, or 4

Known on Windows as Kerberos RC4 encryption

o aes128-cts-hmac-sha1-96, aes128-cts, 0x8, or 8

Known on Windows as Kerberos AES 128 bit encryption

o aes256-cts-hmac-sha1-96, aes256-cts, 0x10, or 16

Known on Windows as Kerberos AES 256 bit encryption

o aes256-cts-hmac-sha1-96-sk, aes256-cts-sk, 0x20, or 32

Allow AES session keys. When this is set, it indicates
to the KDC that AES session keys can be used, even when
aes256-cts and aes128-cts are not set. This allows use
of AES keys against hosts otherwise only configured with
RC4 for ticket keys (which is the default).

Default: kdc default domain supported enctypes = 0 # maps to what
the software supports currently: arcfour-hmac-md5
aes256-cts-hmac-sha1-96-sk

kdc enable fast (G)

With the Samba 4.16 the embedded Heimdal KDC brings support for
RFC6113 FAST, which wasn't available in older Samba versions.

This option is mostly for testing and currently only applies if the
embedded Heimdal KDC is used.

Default: kdc enable fast = yes

kdc force enable rc4 weak session keys (G)

RFC8429 declares that rc4-hmac Kerberos ciphers are weak and there
are known attacks on Active Directory use of this cipher suite.

However for compatibility with Microsoft Windows this option allows
the KDC to assume that regardless of the value set in a service
account's msDS-SupportedEncryptionTypes attribute that a rc4-hmac
Kerberos session key (as distinct from the ticket key, as found in
a service keytab) can be used if the potentially older client
requests it.

Default: kdc force enable rc4 weak session keys = no

kdc supported enctypes (G)

On an active directory domain controller, this is the list of
supported encryption types for local running kdc.

This allows Samba administrators to remove support for weak/unused
encryption types, similar the configuration flexibility provided by
the Network security: Configure encryption types allowed for
Kerberos GPO/Local Policies/Security Options Value, which results
in the
HKEY_LOCAL_MACHINE\SOFTWARE\Microsoft\Windows\CurrentVersion\Policies\System\Kerberos\Parameters\SupportedEncryptionTypes
Registry Value on Windows.

Unlike the Windows registry key (which only takes an base-10
number), in Samba this may also be expressed as hexadecimal or a
list of Kerberos encryption type names.

Specified values are ORed together bitwise, and those currently
supported consist of:

o arcfour-hmac-md5, rc4-hmac, 0x4, or 4

Known on Windows as Kerberos RC4 encryption

o aes128-cts-hmac-sha1-96, aes128-cts, 0x8, or 8

Known on Windows as Kerberos AES 128 bit encryption

o aes256-cts-hmac-sha1-96, aes256-cts, 0x10, or 16

Known on Windows as Kerberos AES 256 bit encryption

Default: kdc supported enctypes = 0 # maps to what the software
supports currently: arcfour-hmac-md5 aes128-cts-hmac-sha1-96
aes256-cts-hmac-sha1-96

keepalive (G)

The value of the parameter (an integer) represents the number of
seconds between keepalive packets. If this parameter is zero, no
keepalive packets will be sent. Keepalive packets, if sent, allow
the server to tell whether a client is still present and
responding.

Keepalives should, in general, not be needed if the socket has the
SO_KEEPALIVE attribute set on it by default. (see socket options).
Basically you should only use this option if you strike
difficulties.

Please note this option only applies to SMB1 client connections,
and has no effect on SMB2 clients.

Default: keepalive = 300

Example: keepalive = 600

kerberos encryption types (G)

This parameter determines the encryption types to use when
operating as a Kerberos client. Possible values are all, strong,
and legacy.

Samba uses a Kerberos library (MIT or Heimdal) to obtain Kerberos
tickets. This library is normally configured outside of Samba,
using the krb5.conf file. This file may also include directives to
configure the encryption types to be used. However, Samba
implements Active Directory protocols and algorithms to locate a
domain controller. In order to force the Kerberos library into
using the correct domain controller, some Samba processes, such as
winbindd(8) and net(8), build a private krb5.conf file for use by
the Kerberos library while being invoked from Samba. This private
file controls all aspects of the Kerberos library operation, and
this parameter controls how the encryption types are configured
within this generated file, and therefore also controls the
encryption types negotiable by Samba.

When set to all, all active directory encryption types are allowed.

When set to strong, only AES-based encryption types are offered.
This can be used in hardened environments to prevent downgrade
attacks.

When set to legacy, only RC4-HMAC-MD5 is allowed. AVOID using this
option, because of CVE-2022-37966 see
https://bugzilla.samba.org/show_bug.cgi?id=15237.

Default: kerberos encryption types = all

kerberos method (G)

Controls how kerberos tickets are verified.

Valid options are:

o secrets only - use only the secrets.tdb for ticket
verification (default)

o system keytab - use only the system keytab for ticket
verification

o dedicated keytab - use a dedicated keytab for ticket
verification

o secrets and keytab - use the secrets.tdb first, then the
system keytab

The major difference between "system keytab" and "dedicated keytab"
is that the latter method relies on kerberos to find the correct
keytab entry instead of filtering based on expected principals.

When the kerberos method is in "dedicated keytab" mode, dedicated
keytab file must be set to specify the location of the keytab file.

Default: kerberos method = default

kernel change notify (G)

This parameter specifies whether Samba should ask the kernel for
change notifications in directories so that SMB clients can refresh
whenever the data on the server changes.

This parameter is only used when your kernel supports change
notification to user programs using the inotify interface.

Default: kernel change notify = yes

kernel oplocks (S)

For UNIXes that support kernel based oplocks (currently only
Linux), this parameter allows the use of them to be turned on or
off. However, this disables Level II oplocks for clients as the
Linux kernel does not support them properly.

Kernel oplocks support allows Samba oplocks to be broken whenever a
local UNIX process or NFS operation accesses a file that smbd(8)
has oplocked. This allows complete data consistency between
SMB/CIFS, NFS and local file access (and is a very cool feature
:-).

If you do not need this interaction, you should disable the
parameter on Linux to get Level II oplocks and the associated
performance benefit.

This parameter defaults to no and is translated to a no-op on
systems that do not have the necessary kernel support.

Default: kernel oplocks = no

kernel share modes (S)

This parameter controls whether SMB share modes are translated into
file system specific sharemode calls.

Kernel share modes provide a minimal level of interoperability with
local UNIX processes and NFS operations by preventing access
corresponding to the SMB share modes. This requires a file system
specific VFS module with proper support.

Note that in order to use SMB2 durable file handles on a share, you
have to turn kernel share modes off.

This parameter defaults to no. Setting it to yes requires a file
system module that supports file system sharemodes, otherwise
attempts to access files will fail with a sharing violation.

Default: kernel share modes = no

kpasswd port (G)

Specifies which ports the Kerberos server should listen on for
password changes.

Default: kpasswd port = 464

krb5 port (G)

Specifies which port the KDC should listen on for Kerberos traffic.

Default: krb5 port = 88

lanman auth (G)

This parameter has been deprecated since Samba 4.11 and support for
LanMan (as distinct from NTLM, NTLMv2 or Kerberos authentication)
will be removed in a future Samba release.

That is, in the future, the current default of lanman auth = no
will be the enforced behaviour.

This parameter determines whether or not smbd(8) will attempt to
authenticate users or permit password changes using the LANMAN
password hash. If disabled, only clients which support NT password
hashes (e.g. Windows NT/2000 clients, smbclient, but not Windows
95/98 or the MS DOS network client) will be able to connect to the
Samba host.

The LANMAN encrypted response is easily broken, due to its
case-insensitive nature, and the choice of algorithm. Servers
without Windows 95/98/ME or MS DOS clients are advised to disable
this option.

When this parameter is set to no this will also result in
sambaLMPassword in Samba's passdb being blanked after the next
password change. As a result of that lanman clients won't be able
to authenticate, even if lanman auth is re-enabled later on.

Unlike the encrypt passwords option, this parameter cannot alter
client behaviour, and the LANMAN response will still be sent over
the network. See the client lanman auth to disable this for Samba's
clients (such as smbclient)

This parameter is overridden by ntlm auth, so unless that it is
also set to ntlmv1-permitted or yes, then only NTLMv2 logins will
be permitted and no LM hash will be stored. All modern clients
support NTLMv2, and but some older clients require special
configuration to use it.

This parameter has no impact on the Samba AD DC, LM authentication
is always disabled and no LM password is ever stored.

Default: lanman auth = no

large readwrite (G)

This parameter determines whether or not smbd(8) supports the new
64k streaming read and write variant SMB requests introduced with
Windows 2000. Note that due to Windows 2000 client redirector bugs
this requires Samba to be running on a 64-bit capable operating
system such as IRIX, Solaris or a Linux 2.4 kernel. Can improve
performance by 10% with Windows 2000 clients. Defaults to on. Not
as tested as some other Samba code paths.

Default: large readwrite = yes

ldap admin dn (G)

The ldap admin dn defines the Distinguished Name (DN) name used by
Samba to contact the ldap server when retrieving user account
information. The ldap admin dn is used in conjunction with the
admin dn password stored in the private/secrets.tdb file. See the
smbpasswd(8) man page for more information on how to accomplish
this.

The ldap admin dn requires a fully specified DN. The ldap suffix is
not appended to the ldap admin dn.

No default

ldap connection timeout (G)

This parameter tells the LDAP library calls which timeout in
seconds they should honor during initial connection establishments
to LDAP servers. It is very useful in failover scenarios in
particular. If one or more LDAP servers are not reachable at all,
we do not have to wait until TCP timeouts are over. This feature
must be supported by your LDAP library.

This parameter is different from ldap timeout which affects
operations on LDAP servers using an existing connection and not
establishing an initial connection.

Default: ldap connection timeout = 2

ldap debug level (G)

This parameter controls the debug level of the LDAP library calls.
In the case of OpenLDAP, it is the same bit-field as understood by
the server and documented in the slapd.conf(5) manpage. A typical
useful value will be 1 for tracing function calls.

The debug output from the LDAP libraries appears with the prefix
[LDAP] in Samba's logging output. The level at which LDAP logging
is printed is controlled by the parameter ldap debug threshold.

Default: ldap debug level = 0

Example: ldap debug level = 1

ldap debug threshold (G)

This parameter controls the Samba debug level at which the ldap
library debug output is printed in the Samba logs. See the
description of ldap debug level for details.

Default: ldap debug threshold = 10

Example: ldap debug threshold = 5

ldap delete dn (G)

This parameter specifies whether a delete operation in the ldapsam
deletes the complete entry or only the attributes specific to
Samba.

Default: ldap delete dn = no

ldap deref (G)

This option controls whether Samba should tell the LDAP library to
use a certain alias dereferencing method. The default is auto,
which means that the default setting of the ldap client library
will be kept. Other possible values are never, finding, searching
and always. Grab your LDAP manual for more information.

Default: ldap deref = auto

Example: ldap deref = searching

ldap follow referral (G)

This option controls whether to follow LDAP referrals or not when
searching for entries in the LDAP database. Possible values are on
to enable following referrals, off to disable this, and auto, to
use the libldap default settings. libldap's choice of following
referrals or not is set in /etc/openldap/ldap.conf with the
REFERRALS parameter as documented in ldap.conf(5).

Default: ldap follow referral = auto

Example: ldap follow referral = off

ldap group suffix (G)

This parameter specifies the suffix that is used for groups when
these are added to the LDAP directory. If this parameter is unset,
the value of ldap suffix will be used instead. The suffix string is
prepended to the ldap suffix string so use a partial DN.

Default: ldap group suffix =

Example: ldap group suffix = ou=Groups

ldap idmap suffix (G)

This parameters specifies the suffix that is used when storing
idmap mappings. If this parameter is unset, the value of ldap
suffix will be used instead. The suffix string is prepended to the
ldap suffix string so use a partial DN.

Default: ldap idmap suffix =

Example: ldap idmap suffix = ou=Idmap

ldap machine suffix (G)

It specifies where machines should be added to the ldap tree. If
this parameter is unset, the value of ldap suffix will be used
instead. The suffix string is prepended to the ldap suffix string
so use a partial DN.

Default: ldap machine suffix =

Example: ldap machine suffix = ou=Computers

ldap max anonymous request size (G)

This parameter specifies the maximum permitted size (in bytes) for
an LDAP request received on an anonymous connection.

If the request size exceeds this limit the request will be
rejected.

Default: ldap max anonymous request size = 256000

Example: ldap max anonymous request size = 500000

ldap max authenticated request size (G)

This parameter specifies the maximum permitted size (in bytes) for
an LDAP request received on an authenticated connection.

If the request size exceeds this limit the request will be
rejected.

Default: ldap max authenticated request size = 16777216

Example: ldap max authenticated request size = 4194304

ldap max search request size (G)

This parameter specifies the maximum permitted size (in bytes) for
an LDAP search request.

If the request size exceeds this limit the request will be
rejected.

Default: ldap max search request size = 256000

Example: ldap max search request size = 4194304

ldap page size (G)

This parameter specifies the number of entries per page.

If the LDAP server supports paged results, clients can request
subsets of search results (pages) instead of the entire list. This
parameter specifies the size of these pages.

Default: ldap page size = 1000

Example: ldap page size = 512

ldap password sync

This parameter is a synonym for ldap passwd sync.

ldap passwd sync (G)

This option is used to define whether or not Samba should sync the
LDAP password with the NT and LM hashes for normal accounts (NOT
for workstation, server or domain trusts) on a password change via
SAMBA.

The ldap passwd sync can be set to one of three values:

o Yes = Try to update the LDAP, NT and LM passwords and
update the pwdLastSet time.

o No = Update NT and LM passwords and update the
pwdLastSet time.

o Only = Only update the LDAP password and let the LDAP
server do the rest.

Default: ldap passwd sync = no

ldap replication sleep (G)

When Samba is asked to write to a read-only LDAP replica, we are
redirected to talk to the read-write master server. This server
then replicates our changes back to the 'local' server, however the
replication might take some seconds, especially over slow links.
Certain client activities, particularly domain joins, can become
confused by the 'success' that does not immediately change the LDAP
back-end's data.

This option simply causes Samba to wait a short time, to allow the
LDAP server to catch up. If you have a particularly high-latency
network, you may wish to time the LDAP replication with a network
sniffer, and increase this value accordingly. Be aware that no
checking is performed that the data has actually replicated.

The value is specified in milliseconds, the maximum value is 5000
(5 seconds).

Default: ldap replication sleep = 1000

ldapsam:editposix (G)

Editposix is an option that leverages ldapsam:trusted to make it
simpler to manage a domain controller eliminating the need to set
up custom scripts to add and manage the posix users and groups.
This option will instead directly manipulate the ldap tree to
create, remove and modify user and group entries. This option also
requires a running winbindd as it is used to allocate new uids/gids
on user/group creation. The allocation range must be therefore
configured.

To use this option, a basic ldap tree must be provided and the ldap
suffix parameters must be properly configured. On virgin servers
the default users and groups (Administrator, Guest, Domain Users,
Domain Admins, Domain Guests) can be precreated with the command
net sam provision. To run this command the ldap server must be
running, Winbindd must be running and the smb.conf ldap options
must be properly configured. The typical ldap setup used with the
ldapsam:trusted = yes option is usually sufficient to use
ldapsam:editposix = yes as well.

An example configuration can be the following:

encrypt passwords = true
passdb backend = ldapsam

ldapsam:trusted=yes
ldapsam:editposix=yes

ldap admin dn = cn=admin,dc=samba,dc=org
ldap delete dn = yes
ldap group suffix = ou=groups
ldap idmap suffix = ou=idmap
ldap machine suffix = ou=computers
ldap user suffix = ou=users
ldap suffix = dc=samba,dc=org

idmap backend = ldap:"ldap://localhost"

idmap uid = 5000-50000
idmap gid = 5000-50000

This configuration assumes a directory layout like described in the
following ldif:

dn: dc=samba,dc=org
objectClass: top
objectClass: dcObject
objectClass: organization
o: samba.org
dc: samba

dn: cn=admin,dc=samba,dc=org
objectClass: simpleSecurityObject
objectClass: organizationalRole
cn: admin
description: LDAP administrator
userPassword: secret

dn: ou=users,dc=samba,dc=org
objectClass: top
objectClass: organizationalUnit
ou: users

dn: ou=groups,dc=samba,dc=org
objectClass: top
objectClass: organizationalUnit
ou: groups

dn: ou=idmap,dc=samba,dc=org
objectClass: top
objectClass: organizationalUnit
ou: idmap

dn: ou=computers,dc=samba,dc=org
objectClass: top
objectClass: organizationalUnit
ou: computers

Default: ldapsam:editposix = no

ldapsam:trusted (G)

By default, Samba as a Domain Controller with an LDAP backend needs
to use the Unix-style NSS subsystem to access user and group
information. Due to the way Unix stores user information in
/etc/passwd and /etc/group this inevitably leads to inefficiencies.
One important question a user needs to know is the list of groups
he is member of. The plain UNIX model involves a complete
enumeration of the file /etc/group and its NSS counterparts in
LDAP. UNIX has optimized functions to enumerate group membership.
Sadly, other functions that are used to deal with user and group
attributes lack such optimization.

To make Samba scale well in large environments, the ldapsam:trusted
= yes option assumes that the complete user and group database that
is relevant to Samba is stored in LDAP with the standard
posixAccount/posixGroup attributes. It further assumes that the
Samba auxiliary object classes are stored together with the POSIX
data in the same LDAP object. If these assumptions are met,
ldapsam:trusted = yes can be activated and Samba can bypass the NSS
system to query user group memberships. Optimized LDAP queries can
greatly speed up domain logon and administration tasks. Depending
on the size of the LDAP database a factor of 100 or more for common
queries is easily achieved.

Default: ldapsam:trusted = no

ldap server require strong auth (G)

The ldap server require strong auth defines whether the ldap server
requires ldap traffic to be signed or signed and encrypted
(sealed). Possible values are no, allow_sasl_over_tls and yes.

A value of no allows simple and sasl binds over all transports.

A value of allow_sasl_over_tls allows simple and sasl binds
(without sign or seal) over TLS encrypted connections. Unencrypted
connections only allow sasl binds with sign or seal.

A value of yes allows only simple binds over TLS encrypted
connections. Unencrypted connections only allow sasl binds with
sign or seal.

Default: ldap server require strong auth = yes

ldap ssl (G)

This option is used to define whether or not Samba should use SSL
when connecting to the ldap server This is NOT related to Samba's
previous SSL support which was enabled by specifying the --with-ssl
option to the configure script.

LDAP connections should be secured where possible. This may be done
setting either this parameter to start tls or by specifying
ldaps:// in the URL argument of passdb backend.

The ldap ssl can be set to one of two values:

o Off = Never use SSL when querying the directory.

o start tls = Use the LDAPv3 StartTLS extended operation
(RFC2830) for communicating with the directory server.

Please note that this parameter does only affect rpc methods.

Default: ldap ssl = start tls

ldap suffix (G)

Specifies the base for all ldap suffixes and for storing the
sambaDomain object.

The ldap suffix will be appended to the values specified for the
ldap user suffix, ldap group suffix, ldap machine suffix, and the
ldap idmap suffix. Each of these should be given only a DN relative
to the ldap suffix.

Default: ldap suffix =

Example: ldap suffix = dc=samba,dc=org

ldap timeout (G)

This parameter defines the number of seconds that Samba should use
as timeout for LDAP operations.

Default: ldap timeout = 15

ldap user suffix (G)

This parameter specifies where users are added to the tree. If this
parameter is unset, the value of ldap suffix will be used instead.
The suffix string is prepended to the ldap suffix string so use a
partial DN.

Default: ldap user suffix =

Example: ldap user suffix = ou=people

level2 oplocks (S)

This parameter controls whether Samba supports level2 (read-only)
oplocks on a share.

Level2, or read-only oplocks allow Windows NT clients that have an
oplock on a file to downgrade from a read-write oplock to a
read-only oplock once a second client opens the file (instead of
releasing all oplocks on a second open, as in traditional,
exclusive oplocks). This allows all openers of the file that
support level2 oplocks to cache the file for read-ahead only (ie.
they may not cache writes or lock requests) and increases
performance for many accesses of files that are not commonly
written (such as application .EXE files).

Once one of the clients which have a read-only oplock writes to the
file all clients are notified (no reply is needed or waited for)
and told to break their oplocks to "none" and delete any read-ahead
caches.

It is recommended that this parameter be turned on to speed access
to shared executables.

For more discussions on level2 oplocks see the CIFS spec.

Currently, if kernel oplocks are supported then level2 oplocks are
not granted (even if this parameter is set to yes). Note also, the
oplocks parameter must be set to yes on this share in order for
this parameter to have any effect.

Default: level2 oplocks = yes

lm announce (G)

This parameter determines if nmbd(8) will produce Lanman announce
broadcasts that are needed by OS/2 clients in order for them to see
the Samba server in their browse list. This parameter can have
three values, yes, no, or auto. The default is auto. If set to no
Samba will never produce these broadcasts. If set to yes Samba will
produce Lanman announce broadcasts at a frequency set by the
parameter lm interval. If set to auto Samba will not send Lanman
announce broadcasts by default but will listen for them. If it
hears such a broadcast on the wire it will then start sending them
at a frequency set by the parameter lm interval.

Default: lm announce = auto

Example: lm announce = yes

lm interval (G)

If Samba is set to produce Lanman announce broadcasts needed by
OS/2 clients (see the lm announce parameter) then this parameter
defines the frequency in seconds with which they will be made. If
this is set to zero then no Lanman announcements will be made
despite the setting of the lm announce parameter.

Default: lm interval = 60

Example: lm interval = 120

load printers (G)

A boolean variable that controls whether all printers in the
printcap will be loaded for browsing by default. See the printers
section for more details.

Default: load printers = yes

local master (G)

This option allows nmbd(8) to try and become a local master browser
on a subnet. If set to no then nmbd will not attempt to become a
local master browser on a subnet and will also lose in all browsing
elections. By default this value is set to yes. Setting this value
to yes doesn't mean that Samba will become the local master browser
on a subnet, just that nmbd will participate in elections for local
master browser.

Setting this value to no will cause nmbd never to become a local
master browser.

Default: local master = yes

lock dir

This parameter is a synonym for lock directory.

lock directory (G)

This option specifies the directory where lock files will be
placed. The lock files are used to implement the max connections
option.

Note: This option can not be set inside registry configurations.

The files placed in this directory are not required across service
restarts and can be safely placed on volatile storage (e.g. tmpfs
in Linux)

Default: lock directory = ${prefix}/var/lock

Example: lock directory = /var/run/samba/locks

locking (S)

This controls whether or not locking will be performed by the
server in response to lock requests from the client.

If locking = no, all lock and unlock requests will appear to
succeed and all lock queries will report that the file in question
is available for locking.

If locking = yes, real locking will be performed by the server.

This option may be useful for read-only filesystems which may not
need locking (such as CDROM drives), although setting this
parameter of no is not really recommended even in this case.

Be careful about disabling locking either globally or in a specific
service, as lack of locking may result in data corruption. You
should never need to set this parameter.

Default: locking = yes

lock spin time (G)

The time in milliseconds that smbd should keep waiting to see if a
failed lock request can be granted. This parameter has changed in
default value from Samba 3.0.23 from 10 to 200. The associated lock
spin count parameter is no longer used in Samba 3.0.24. You should
not need to change the value of this parameter.

Default: lock spin time = 200

log file (G)

This option allows you to override the name of the Samba log file
(also known as the debug file).

This option takes the standard substitutions, allowing you to have
separate log files for each user or machine.

No default

Example: log file = /usr/local/samba/var/log.%m

logging (G)

This parameter configures logging backends. Multiple backends can
be specified at the same time, with different log levels for each
backend. The parameter is a list of backends, where each backend is
specified as backend[:option][@loglevel].

The 'option' parameter can be used to pass backend-specific
options.

The log level for a backend is optional, if it is not set for a
backend, all messages are sent to this backend. The parameter log
level determines overall log levels, while the log levels specified
here define what is sent to the individual backends.

When logging is set, it overrides the syslog and syslog only
parameters.

Some backends are only available when Samba has been compiled with
the additional libraries. The overall list of logging backends:

o syslog

o file

o systemd

o lttng

o gpfs

o ringbuf

The ringbuf backend supports an optional size argument to change
the buffer size used, the default is 1 MB: ringbuf:size=NBYTES

Default: logging =

Example: logging = syslog@1 file

debuglevel

This parameter is a synonym for log level.

log level (G)

The value of the parameter (a string) allows the debug level
(logging level) to be specified in the smb.conf file.

This parameter has been extended since the 2.2.x series, now it
allows one to specify the debug level for multiple debug classes
and distinct logfiles for debug classes. This is to give greater
flexibility in the configuration of the system. The following debug
classes are currently implemented:

o all

o tdb

o printdrivers

o lanman

o smb

o rpc_parse

o rpc_srv

o rpc_cli

o passdb

o sam

o auth

o winbind

o vfs

o idmap

o quota

o acls

o locking

o msdfs

o dmapi

o registry

o scavenger

o dns

o ldb

o tevent

o auth_audit

o auth_json_audit

o kerberos

o drs_repl

o smb2

o smb2_credits

o dsdb_audit

o dsdb_json_audit

o dsdb_password_audit

o dsdb_password_json_audit

o dsdb_transaction_audit

o dsdb_transaction_json_audit

o dsdb_group_audit

o dsdb_group_json_audit

Various modules register dynamic debug classes at first usage:

o catia

o dfs_samba4

o extd_audit

o fileid

o fruit

o full_audit

o media_harmony

o preopen

o recycle

o shadow_copy

o unityed_media

o virusfilter

To configure the logging for specific classes to go into a
different file then log file, you can append @PATH to the class, eg
log level = 1 full_audit:1@/var/log/audit.log.

Authentication and authorization audit information is logged under
the auth_audit, and if Samba was not compiled with --without-json,
a JSON representation is logged under auth_json_audit.

Support is comprehensive for all authentication and authorisation
of user accounts in the Samba Active Directory Domain Controller,
as well as the implicit authentication in password changes. In the
file server, NTLM authentication, SMB and RPC authorization is
covered.

Log levels for auth_audit and auth_audit_json are:

o 2: Authentication Failure

o 3: Authentication Success

o 4: Authorization Success

o 5: Anonymous Authentication and Authorization Success

Changes to the AD DC sam.ldb database are logged under the
dsdb_audit and a JSON representation is logged under
dsdb_json_audit.

Group membership changes to the AD DC sam.ldb database are logged
under the dsdb_group_audit and a JSON representation is logged
under dsdb_group_json_audit.

Log levels for dsdb_audit, dsdb_json_audit, dsdb_group_audit,
dsdb_group_json_audit and dsdb_json_audit are:

o 5: Database modifications

o 5: Replicated updates from another DC

Password changes and Password resets in the AD DC are logged under
dsdb_password_audit and a JSON representation is logged under the
dsdb_password_json_audit. Password changes will also appears as
authentication events via auth_audit and auth_audit_json.

Log levels for dsdb_password_audit and dsdb_password_json_audit
are:

o 5: Successful password changes and resets

Transaction rollbacks and prepare commit failures are logged under
the dsdb_transaction_audit and a JSON representation is logged
under the dsdb_transaction_json_audit.

Log levels for dsdb_transaction_audit and dsdb_transaction_json
are:

o 5: Transaction failure (rollback)

o 10: Transaction success (commit)

Transaction roll-backs are possible in Samba, and whilst they
rarely reflect anything more than the failure of an individual
operation (say due to the add of a conflicting record), they are
possible. Audit logs are already generated and sent to the system
logs before the transaction is complete. Logging the transaction
details allows the identification of password and sam.ldb
operations that have been rolled back, and so have not actually
persisted.

Warning
Changes to sam.ldb made locally by the root user with direct
access to the database are not logged to the system logs, but
to the administrator's own console. While less than ideal, any
user able to make such modifications could disable the audit
logging in any case.
Default: log level = 0

Example: log level = 3 passdb:5 auth:10 winbind:2

Example: log level = 1 full_audit:1@/var/log/audit.log winbind:2

log nt token command (G)

This option can be set to a command that will be called when new nt
tokens are created.

This is only useful for development purposes.

Default: log nt token command =

logon drive (G)

This parameter specifies the local path to which the home directory
will be connected (see logon home) and is only used by NT
Workstations.

Note that this option is only useful if Samba is set up as a logon
server.

Default: logon drive =

Example: logon drive = h:

logon home (G)

This parameter specifies the home directory location when a
Win95/98 or NT Workstation logs into a Samba PDC. It allows you to
do

C:\>NET USE H: /HOME

from a command prompt, for example.

This option takes the standard substitutions, allowing you to have
separate logon scripts for each user or machine.

This parameter can be used with Win9X workstations to ensure that
roaming profiles are stored in a subdirectory of the user's home
directory. This is done in the following way:

logon home = \\%N\%U\profile

This tells Samba to return the above string, with substitutions
made when a client requests the info, generally in a NetUserGetInfo
request. Win9X clients truncate the info to \\server\share when a
user does net use /home but use the whole string when dealing with
profiles.

Note that in prior versions of Samba, the logon path was returned
rather than logon home. This broke net use /home but allowed
profiles outside the home directory. The current implementation is
correct, and can be used for profiles if you use the above trick.

Disable this feature by setting logon home = "" - using the empty
string.

This option is only useful if Samba is set up as a logon server.

Default: logon home = \\%N\%U

Example: logon home = \\remote_smb_server\%U

logon path (G)

This parameter specifies the directory where roaming profiles
(Desktop, NTuser.dat, etc) are stored. Contrary to previous
versions of these manual pages, it has nothing to do with Win 9X
roaming profiles. To find out how to handle roaming profiles for
Win 9X system, see the logon home parameter.

This option takes the standard substitutions, allowing you to have
separate logon scripts for each user or machine. It also specifies
the directory from which the "Application Data", desktop, start
menu, network neighborhood, programs and other folders, and their
contents, are loaded and displayed on your Windows NT client.

The share and the path must be readable by the user for the
preferences and directories to be loaded onto the Windows NT
client. The share must be writeable when the user logs in for the
first time, in order that the Windows NT client can create the
NTuser.dat and other directories. Thereafter, the directories and
any of the contents can, if required, be made read-only. It is not
advisable that the NTuser.dat file be made read-only - rename it to
NTuser.man to achieve the desired effect (a MANdatory profile).

Windows clients can sometimes maintain a connection to the [homes]
share, even though there is no user logged in. Therefore, it is
vital that the logon path does not include a reference to the homes
share (i.e. setting this parameter to \\%N\homes\profile_path will
cause problems).

This option takes the standard substitutions, allowing you to have
separate logon scripts for each user or machine.

Warning
Do not quote the value. Setting this as "\\%N\profile\%U" will
break profile handling. Where the tdbsam or ldapsam passdb
backend is used, at the time the user account is created the
value configured for this parameter is written to the passdb
backend and that value will over-ride the parameter value
present in the smb.conf file. Any error present in the passdb
backend account record must be edited using the appropriate
tool (pdbedit on the command-line, or any other locally
provided system tool).
Note that this option is only useful if Samba is set up as a domain
controller.

Disable the use of roaming profiles by setting the value of this
parameter to the empty string. For example, logon path = "". Take
note that even if the default setting in the smb.conf file is the
empty string, any value specified in the user account settings in
the passdb backend will over-ride the effect of setting this
parameter to null. Disabling of all roaming profile use requires
that the user account settings must also be blank.

An example of use is:

logon path = \\PROFILESERVER\PROFILE\%U

Default: logon path = \\%N\%U\profile

logon script (G)

This parameter specifies the batch file (.bat) or NT command file
(.cmd) to be downloaded and run on a machine when a user
successfully logs in. The file must contain the DOS style CR/LF
line endings. Using a DOS-style editor to create the file is
recommended.

The script must be a relative path to the [netlogon] service. If
the [netlogon] service specifies a path of
/usr/local/samba/netlogon, and logon script = STARTUP.BAT, then the
file that will be downloaded is:

/usr/local/samba/netlogon/STARTUP.BAT

The contents of the batch file are entirely your choice. A
suggested command would be to add NET TIME \\SERVER /SET /YES, to
force every machine to synchronize clocks with the same time
server. Another use would be to add NET USE U: \\SERVER\UTILS for
commonly used utilities, or

NET USE Q: \\SERVER\ISO9001_QA

for example.

Note that it is particularly important not to allow write access to
the [netlogon] share, or to grant users write permission on the
batch files in a secure environment, as this would allow the batch
files to be arbitrarily modified and security to be breached.

This option takes the standard substitutions, allowing you to have
separate logon scripts for each user or machine.

This option is only useful if Samba is set up as a logon server in
a classic domain controller role. If Samba is set up as an Active
Directory domain controller, LDAP attribute scriptPath is used
instead. For configurations where passdb backend = ldapsam is in
use, this option only defines a default value in case LDAP
attribute sambaLogonScript is missing.

Default: logon script =

Example: logon script = scripts\%U.bat

log writeable files on exit (G)

When the network connection between a CIFS client and Samba dies,
Samba has no option but to simply shut down the server side of the
network connection. If this happens, there is a risk of data
corruption because the Windows client did not complete all write
operations that the Windows application requested. Setting this
option to "yes" makes smbd log with a level 0 message a list of all
files that have been opened for writing when the network connection
died. Those are the files that are potentially corrupted. It is
meant as an aid for the administrator to give him a list of files
to do consistency checks on.

Default: log writeable files on exit = no

lppause command (S)

This parameter specifies the command to be executed on the server
host in order to stop printing or spooling a specific print job.

This command should be a program or script which takes a printer
name and job number to pause the print job. One way of implementing
this is by using job priorities, where jobs having a too low
priority won't be sent to the printer.

If a %p is given then the printer name is put in its place. A %j is
replaced with the job number (an integer). On HPUX (see
printing=hpux ), if the -p%p option is added to the lpq command,
the job will show up with the correct status, i.e. if the job
priority is lower than the set fence priority it will have the
PAUSED status, whereas if the priority is equal or higher it will
have the SPOOLED or PRINTING status.

Note that it is good practice to include the absolute path in the
lppause command as the PATH may not be available to the server.

Currently no default value is given to this string, unless the
value of the printing parameter is SYSV, in which case the default
is : lp -i %p-%j -H hold or if the value of the printing parameter
is SOFTQ, then the default is: qstat -s -j%j -h.

Default: lppause command = # determined by printing parameter

Example: lppause command = /usr/bin/lpalt %p-%j -p0

lpq cache time (G)

This controls how long lpq info will be cached for to prevent the
lpq command being called too often. A separate cache is kept for
each variation of the lpq command used by the system, so if you use
different lpq commands for different users then they won't share
cache information.

The cache files are stored in /tmp/lpq.xxxx where xxxx is a hash of
the lpq command in use.

The default is 30 seconds, meaning that the cached results of a
previous identical lpq command will be used if the cached data is
less than 30 seconds old. A large value may be advisable if your
lpq command is very slow.

A value of 0 will disable caching completely.

Default: lpq cache time = 30

Example: lpq cache time = 10

lpq command (S)

This parameter specifies the command to be executed on the server
host in order to obtain lpq-style printer status information.

This command should be a program or script which takes a printer
name as its only parameter and outputs printer status information.

Currently nine styles of printer status information are supported;
BSD, AIX, LPRNG, PLP, SYSV, HPUX, QNX, CUPS, and SOFTQ. This covers
most UNIX systems. You control which type is expected using the
printing = option.

Some clients (notably Windows for Workgroups) may not correctly
send the connection number for the printer they are requesting
status information about. To get around this, the server reports on
the first printer service connected to by the client. This only
happens if the connection number sent is invalid.

If a %p is given then the printer name is put in its place.
Otherwise it is placed at the end of the command.

Note that it is good practice to include the absolute path in the
lpq command as the $PATH may not be available to the server. When
compiled with the CUPS libraries, no lpq command is needed because
smbd will make a library call to obtain the print queue listing.

Default: lpq command = # determined by printing parameter

Example: lpq command = /usr/bin/lpq -P%p

lpresume command (S)

This parameter specifies the command to be executed on the server
host in order to restart or continue printing or spooling a
specific print job.

This command should be a program or script which takes a printer
name and job number to resume the print job. See also the lppause
command parameter.

If a %p is given then the printer name is put in its place. A %j is
replaced with the job number (an integer).

Note that it is good practice to include the absolute path in the
lpresume command as the PATH may not be available to the server.

See also preexec close and postexec.

Default: preexec =

Example: preexec = echo \"%u connected to %S from %m (%I)\" __
/tmp/log

preexec close (S)

This boolean option controls whether a non-zero return code from
preexec should close the service being connected to.

Default: preexec close = no

prefered master

This parameter is a synonym for preferred master.

preferred master (G)

This boolean parameter controls if nmbd(8) is a preferred master
browser for its workgroup.

If this is set to yes, on startup, nmbd will force an election, and
it will have a slight advantage in winning the election. It is
recommended that this parameter is used in conjunction with domain
master = yes, so that nmbd can guarantee becoming a domain master.

Use this option with caution, because if there are several hosts
(whether Samba servers, Windows 95 or NT) that are preferred master
browsers on the same subnet, they will each periodically and
continuously attempt to become the local master browser. This will
result in unnecessary broadcast traffic and reduced browsing
capabilities.

Default: preferred master = auto

prefork backoff increment (G)

This option specifies the number of seconds added to the delay
before a prefork master or worker process is restarted. The restart
is initially zero, the prefork backoff increment is added to the
delay on each restart up to the value specified by "prefork maximum
backoff".

Additionally set the backoff for an individual service by using
"prefork backoff increment: service name" i.e. "prefork backoff
increment:ldap = 2" to set the backoff increment to 2.

If the backoff increment is 2 and the maximum backoff is 5. There
will be a zero second delay for the first restart. A two second
delay for the second restart. A four second delay for the third and
any subsequent restarts

Default: prefork backoff increment = 10

prefork children (G)

This option controls the number of worker processes that are
started for each service when prefork process model is enabled (see
samba(8) -M) The prefork children are only started for those
services that support prefork (currently ldap, kdc and netlogon).
For processes that don't support preforking all requests are
handled by a single process for that service.

This should be set to a small multiple of the number of CPU's
available on the server

Additionally the number of prefork children can be specified for an
individual service by using "prefork children: service name" i.e.
"prefork children:ldap = 8" to set the number of ldap worker
processes.

Default: prefork children = 4

prefork maximum backoff (G)

This option controls the maximum delay before a failed pre-fork
process is restarted.

Default: prefork maximum backoff = 120

preload modules (G)

This is a list of paths to modules that should be loaded into smbd
before a client connects. This improves the speed of smbd when
reacting to new connections somewhat.

Default: preload modules =

Example: preload modules = /usr/lib/samba/passdb/mysql.so

preserve case (S)

This controls if new filenames are created with the case that the
client passes, or if they are forced to be the default case.

See the section on NAME MANGLING for a fuller discussion.

Default: preserve case = yes

print ok

This parameter is a synonym for printable.

printable (S)

If this parameter is yes, then clients may open, write to and
submit spool files on the directory specified for the service.

Note that a printable service will ALWAYS allow writing to the
service path (user privileges permitting) via the spooling of print
data. The read only parameter controls only non-printing access to
the resource.

Default: printable = no

printcap cache time (G)

This option specifies the number of seconds before the printing
subsystem is again asked for the known printers.

Setting this parameter to 0 disables any rescanning for new or
removed printers after the initial startup.

Default: printcap cache time = 750

Example: printcap cache time = 600

printcap

This parameter is a synonym for printcap name.

printcap name (G)

This parameter may be used to override the compiled-in default
printcap name used by the server (usually /etc/printcap). See the
discussion of the [printers] section above for reasons why you
might want to do this.

To use the CUPS printing interface set printcap name = cups. This
should be supplemented by an additional setting printing = cups in
the [global] section. printcap name = cups will use the "dummy"
printcap created by CUPS, as specified in your CUPS configuration
file.

On System V systems that use lpstat to list available printers you
can use printcap name = lpstat to automatically obtain lists of
available printers. This is the default for systems that define
SYSV at configure time in Samba (this includes most System V based
systems). If
printcap name is set to lpstat on these systems then Samba will
launch lpstat -v and attempt to parse the output to obtain a
printer list.

A minimal printcap file would look something like this:

where the '|' separates aliases of a printer. The fact that the
second alias has a space in it gives a hint to Samba that it's a
comment.

Note
Under AIX the default printcap name is /etc/qconfig. Samba will
assume the file is in AIX qconfig format if the string qconfig
appears in the printcap filename.
Default: printcap name = /etc/printcap

Example: printcap name = /etc/myprintcap

print command (S)

After a print job has finished spooling to a service, this command
will be used via a system() call to process the spool file.
Typically the command specified will submit the spool file to the
host's printing subsystem, but there is no requirement that this be
the case. The server will not remove the spool file, so whatever
command you specify should remove the spool file when it has been
processed, otherwise you will need to manually remove old spool
files.

The print command is simply a text string. It will be used verbatim
after macro substitutions have been made:

%s, %f - the path to the spool file name

%p - the appropriate printer name

%J - the job name as transmitted by the client.

%c - The number of printed pages of the spooled job (if known).

%z - the size of the spooled print job (in bytes)

The print command MUST contain at least one occurrence of %s or %f
- the %p is optional. At the time a job is submitted, if no printer
name is supplied the %p will be silently removed from the printer
command.

If specified in the [global] section, the print command given will
be used for any printable service that does not have its own print
command specified.

If there is neither a specified print command for a printable
service nor a global print command, spool files will be created but
not processed and (most importantly) not removed.

Note that printing may fail on some UNIXes from the nobody account.
If this happens then create an alternative guest account that can
print and set the guest account in the [global] section.

You can form quite complex print commands by realizing that they
are just passed to a shell. For example the following will log a
print job, print the file, then remove it. Note that ';' is the
usual separator for command in shell scripts.

print command = echo Printing %s >> /tmp/print.log; lpr -P %p %s;
rm %s

You may have to vary this command considerably depending on how you
normally print files on your system. The default for the parameter
varies depending on the setting of the printing parameter.

Default: For printing = BSD, AIX, QNX, LPRNG or PLP :

print command = lpr -r -P%p %s

For printing = SYSV or HPUX :

print command = lp -c -d%p %s; rm %s

For printing = SOFTQ :

print command = lp -d%p -s %s; rm %s

For printing = CUPS : If SAMBA is compiled against libcups, then
printcap = cups uses the CUPS API to submit jobs, etc. Otherwise it
maps to the System V commands with the -oraw option for printing,
i.e. it uses lp -c -d%p -oraw; rm %s. With printing = cups, and if
SAMBA is compiled against libcups, any manually set print command
will be ignored.

No default

Example: print command = /usr/local/samba/bin/myprintscript %p %s

printer

This parameter is a synonym for printer name.

printer name (S)

This parameter specifies the name of the printer to which print
jobs spooled through a printable service will be sent.

If specified in the [global] section, the printer name given will
be used for any printable service that does not have its own
printer name specified.

The default value of the printer name may be lp on many systems.

Default: printer name =

Example: printer name = laserwriter

printing (S)

This parameters controls how printer status information is
interpreted on your system. It also affects the default values for
the print command, lpq command, lppause command , lpresume command,
and lprm command if specified in the [global] section.

Currently nine printing styles are supported. They are BSD, AIX,
LPRNG, PLP, SYSV, HPUX, QNX, SOFTQ, CUPS and IPRINT.

Be aware that CUPS and IPRINT are only available if the CUPS
development library was available at the time Samba was compiled or
packaged.

To see what the defaults are for the other print commands when
using the various options use the testparm(1) program.

This option can be set on a per printer basis. Please be aware
however, that you must place any of the various printing commands
(e.g. print command, lpq command, etc...) after defining the value
for the printing option since it will reset the printing commands
to default values.

See also the discussion in the [printers] section.

See testparm -v. for the default value on your system

Default: printing = # Depends on the operating system

printjob username (S)

This parameter specifies which user information will be passed to
the printing system. Usually, the username is sent, but in some
cases, e.g. the domain prefix is useful, too.

Default: printjob username = %U

Example: printjob username = %D\%U

print notify backchannel (S)

Windows print clients can update print queue status by expecting
the server to open a backchannel SMB connection to them. Due to
client firewall settings this can cause considerable timeouts and
will often fail, as there is no guarantee the client is even
running an SMB server. By default, the Samba print server will not
try to connect back to clients, and will treat corresponding
requests as if the connection back to the client failed.

Default: print notify backchannel = no

private directory

This parameter is a synonym for private dir.

private dir (G)

This parameters defines the directory smbd will use for storing
such files as smbpasswd and secrets.tdb.

Default: private dir = ${prefix}/private

queuepause command (S)

This parameter specifies the command to be executed on the server
host in order to pause the printer queue.

This command should be a program or script which takes a printer
name as its only parameter and stops the printer queue, such that
no longer jobs are submitted to the printer.

This command is not supported by Windows for Workgroups, but can be
issued from the Printers window under Windows 95 and NT.

If a %p is given then the printer name is put in its place.
Otherwise it is placed at the end of the command.

Note that it is good practice to include the absolute path in the
command as the PATH may not be available to the server.

Default: queuepause command = # determined by printing parameter

Example: queuepause command = disable %p

queueresume command (S)

This parameter specifies the command to be executed on the server
host in order to resume the printer queue. It is the command to
undo the behavior that is caused by the previous parameter
(queuepause command).

This command should be a program or script which takes a printer
name as its only parameter and resumes the printer queue, such that
queued jobs are resubmitted to the printer.

This command is not supported by Windows for Workgroups, but can be
issued from the Printers window under Windows 95 and NT.

If a %p is given then the printer name is put in its place.
Otherwise it is placed at the end of the command.

Note that it is good practice to include the absolute path in the
command as the PATH may not be available to the server.

Default: queueresume command = # determined by printing parameter

Example: queueresume command = enable %p

raw NTLMv2 auth (G)

This parameter has been deprecated since Samba 4.13 and support for
NTLMv2 authentication without NTLMSSP will be removed in a future
Samba release.

That is, in the future, the current default of raw NTLMv2 auth = no
will be the enforced behaviour.

This parameter determines whether or not smbd(8) will allow SMB1
clients without extended security (without SPNEGO) to use NTLMv2
authentication.

If this option, lanman auth and ntlm auth are all disabled, then
only clients with SPNEGO support will be permitted. That means
NTLMv2 is only supported within NTLMSSP.

Default: raw NTLMv2 auth = no

read list (S)

This is a list of users that are given read-only access to a
service. If the connecting user is in this list then they will not
be given write access, no matter what the read only option is set
to. The list can include group names using the syntax described in
the invalid users parameter.

Default: read list =

Example: read list = mary, @students

read only (S)

An inverted synonym is writeable.

If this parameter is yes, then users of a service may not create or
modify files in the service's directory.

Note that a printable service (printable = yes) will ALWAYS allow
writing to the directory (user privileges permitting), but only via
spooling operations.

Default: read only = yes

read raw (G)

This is ignored if async smb echo handler is set, because this
feature is incompatible with raw read SMB requests

If enabled, raw reads allow reads of 65535 bytes in one packet.
This typically provides a major performance benefit for some very,
very old clients.

However, some clients either negotiate the allowable block size
incorrectly or are incapable of supporting larger block sizes, and
for these clients you may need to disable raw reads.

In general this parameter should be viewed as a system tuning tool
and left severely alone.

Default: read raw = yes

realm (G)

This option specifies the kerberos realm to use. The realm is used
as the ADS equivalent of the NT4 domain. It is usually set to the
DNS name of the kerberos server.

Default: realm =

Example: realm = mysambabox.mycompany.com

registry shares (G)

This turns on or off support for share definitions read from
registry. Shares defined in smb.conf take precedence over shares
with the same name defined in registry. See the section on
registry-based configuration for details.

Note that this parameter defaults to no, but it is set to yes when
config backend is set to registry.

Default: registry shares = no

Example: registry shares = yes

reject md5 clients (G)

This option is deprecated and will be removed in a future release,
as it is a security problem if not set to "yes" (which will be the
hardcoded behavior in the future).

This option controls whether the netlogon server (currently only in
'active directory domain controller' mode), will reject clients
which does not support NETLOGON_NEG_SUPPORTS_AES.

Support for NETLOGON_NEG_SUPPORTS_AES was added in Windows starting
with Server 2008R2 and Windows 7, it's available in Samba starting
with 4.0, however third party domain members like NetApp ONTAP
still uses RC4 (HMAC-MD5), see
https://www.samba.org/samba/security/CVE-2022-38023.html for more
details.

The default changed from 'no' to 'yes', with the patches for
CVE-2022-38023 see
https://bugzilla.samba.org/show_bug.cgi?id=15240.

Avoid using this option! Use an explicit per machine account
'server reject md5 schannel:COMPUTERACCOUNT' instead! Which is
available with the patches for CVE-2022-38023 see
https://bugzilla.samba.org/show_bug.cgi?id=15240.

Samba will log an error in the log files at log level 0 if legacy a
client is rejected or allowed without an explicit, 'server reject
md5 schannel:COMPUTERACCOUNT = no' option for the client. The
message will indicate the explicit 'server reject md5
schannel:COMPUTERACCOUNT = no' line to be added, if the legacy
client software requires it. (The log level can be adjusted with
'CVE_2022_38023:error_debug_level = 1' in order to complain only at
a higher log level).

This allows admins to use "no" only for a short grace period, in
order to collect the explicit 'server reject md5
schannel:COMPUTERACCOUNT = no' options.

When set to 'yes' this option overrides the 'allow nt4
crypto:COMPUTERACCOUNT' and 'allow nt4 crypto' options and implies
'allow nt4 crypto:COMPUTERACCOUNT = no'.

Default: reject md5 clients = yes

server reject md5 schannel:COMPUTERACCOUNT (G)

If you still have legacy domain members or trusted domains, which
required "reject md5 clients = no" before, it is possible to
specify an explicit exception per computer account by setting
'server reject md5 schannel:COMPUTERACCOUNT = no'. Note that
COMPUTERACCOUNT has to be the sAMAccountName value of the computer
account (including the trailing '$' sign).

Samba will log a complaint in the log files at log level 0 about
the security problem if the option is set to "no", but the related
computer does not require it. (The log level can be adjusted with
'CVE_2022_38023:warn_about_unused_debug_level = 1' in order to
complain only at a higher log level).

Samba will log a warning in the log files at log level 5 if a
setting is still needed for the specified computer account.

See CVE-2022-38023,
https://bugzilla.samba.org/show_bug.cgi?id=15240.

This option overrides the reject md5 clients option.

When set to 'yes' this option overrides the 'allow nt4
crypto:COMPUTERACCOUNT' and 'allow nt4 crypto' options and implies
'allow nt4 crypto:COMPUTERACCOUNT = no'.

server reject md5 schannel:LEGACYCOMPUTER1$ = no
server reject md5 schannel:NASBOX$ = no
server reject md5 schannel:LEGACYCOMPUTER2$ = no

No default

reject md5 servers (G)

This option controls whether winbindd requires support for aes
support for the netlogon secure channel.

The following flags will be required NETLOGON_NEG_ARCFOUR,
NETLOGON_NEG_SUPPORTS_AES, NETLOGON_NEG_PASSWORD_SET2 and
NETLOGON_NEG_AUTHENTICATED_RPC.

You can set this to yes if all domain controllers support aes. This
will prevent downgrade attacks.

The behavior can be controlled per netbios domain by using 'reject
md5 servers:NETBIOSDOMAIN = no' as option.

The default changed from 'no' to 'yes, with the patches for
CVE-2022-38023, see
https://bugzilla.samba.org/show_bug.cgi?id=15240

This option overrides the require strong key option.

Default: reject md5 servers = yes

remote announce (G)

This option allows you to setup nmbd(8) to periodically announce
itself to arbitrary IP addresses with an arbitrary workgroup name.

This is useful if you want your Samba server to appear in a remote
workgroup for which the normal browse propagation rules don't work.
The remote workgroup can be anywhere that you can send IP packets
to.

For example:

remote announce = 192.168.2.255/SERVERS 192.168.4.255/STAFF

the above line would cause nmbd to announce itself to the two given
IP addresses using the given workgroup names. If you leave out the
workgroup name, then the one given in the workgroup parameter is
used instead.

The IP addresses you choose would normally be the broadcast
addresses of the remote networks, but can also be the IP addresses
of known browse masters if your network config is that stable.

See the chapter on Network Browsing in the Samba-HOWTO book.

Default: remote announce =

remote browse sync (G)

This option allows you to setup nmbd(8) to periodically request
synchronization of browse lists with the master browser of a Samba
server that is on a remote segment. This option will allow you to
gain browse lists for multiple workgroups across routed networks.
This is done in a manner that does not work with any non-Samba
servers.

This is useful if you want your Samba server and all local clients
to appear in a remote workgroup for which the normal browse
propagation rules don't work. The remote workgroup can be anywhere
that you can send IP packets to.

For example:

remote browse sync = 192.168.2.255 192.168.4.255

the above line would cause nmbd to request the master browser on
the specified subnets or addresses to synchronize their browse
lists with the local server.

The IP addresses you choose would normally be the broadcast
addresses of the remote networks, but can also be the IP addresses
of known browse masters if your network config is that stable. If a
machine IP address is given Samba makes NO attempt to validate that
the remote machine is available, is listening, nor that it is in
fact the browse master on its segment.

The remote browse sync may be used on networks where there is no
WINS server, and may be used on disjoint networks where each
network has its own WINS server.

Default: remote browse sync =

rename user script (G)

This is the full pathname to a script that will be run as root by
smbd(8) under special circumstances described below.

When a user with admin authority or SeAddUserPrivilege rights
renames a user (e.g.: from the NT4 User Manager for Domains), this
script will be run to rename the POSIX user. Two variables, %uold
and %unew, will be substituted with the old and new usernames,
respectively. The script should return 0 upon successful
completion, and nonzero otherwise.

Note
The script has all responsibility to rename all the necessary
data that is accessible in this posix method. This can mean
different requirements for different backends. The tdbsam and
smbpasswd backends will take care of the contents of their
respective files, so the script is responsible only for
changing the POSIX username, and other data that may required
for your circumstances, such as home directory. Please also
consider whether or not you need to rename the actual home
directories themselves. The ldapsam backend will not make any
changes, because of the potential issues with renaming the LDAP
naming attribute. In this case the script is responsible for
changing the attribute that samba uses (uid) for locating
users, as well as any data that needs to change for other
applications using the same directory.
Default: rename user script =

require strong key (G)

This option controls whether winbindd requires support for md5
strong key support for the netlogon secure channel.

The following flags will be required NETLOGON_NEG_STRONG_KEYS,
NETLOGON_NEG_ARCFOUR and NETLOGON_NEG_AUTHENTICATED_RPC.

You can set this to no if some domain controllers only support des.
This might allows weak crypto to be negotiated, may via downgrade
attacks.

The behavior can be controlled per netbios domain by using 'require
strong key:NETBIOSDOMAIN = no' as option.

Note for active directory domain this option is hardcoded to 'yes'

This option is over-ridden by the reject md5 servers option.

This option overrides the client schannel option.

Default: require strong key = yes

reset on zero vc (G)

This boolean option controls whether an incoming SMB1 session setup
should kill other connections coming from the same IP. This matches
the default Windows 2003 behaviour. Setting this parameter to yes
becomes necessary when you have a flaky network and windows decides
to reconnect while the old connection still has files with share
modes open. These files become inaccessible over the new
connection. The client sends a zero VC on the new connection, and
Windows 2003 kills all other connections coming from the same IP.
This way the locked files are accessible again. Please be aware
that enabling this option will kill connections behind a
masquerading router, and will not trigger for clients that only use
SMB2 or SMB3.

Default: reset on zero vc = no

restrict anonymous (G)

The setting of this parameter determines whether SAMR and LSA
DCERPC services can be accessed anonymously. This corresponds to
the following Windows Server registry options:

HKEY_LOCAL_MACHINE\SYSTEM\CurrentControlSet\Control\Lsa\RestrictAnonymous

The option also affects the browse option which is required by
legacy clients which rely on Netbios browsing. While modern Windows
version should be fine with restricting the access there could
still be applications relying on anonymous access.

Setting restrict anonymous = 1 will disable anonymous SAMR access.

Setting restrict anonymous = 2 will, in addition to restricting
SAMR access, disallow anonymous connections to the IPC$ share in
general. Setting guest ok = yes on any share will remove the
security advantage.

Default: restrict anonymous = 0

root

This parameter is a synonym for root directory.

root dir

This parameter is a synonym for root directory.

root directory (G)

The server will chroot() (i.e. Change its root directory) to this
directory on startup. This is not strictly necessary for secure
operation. Even without it the server will deny access to files not
in one of the service entries. It may also check for, and deny
access to, soft links to other parts of the filesystem, or attempts
to use ".." in file names to access other directories (depending on
the setting of the wide links parameter).

Adding a root directory entry other than "/" adds an extra level of
security, but at a price. It absolutely ensures that no access is
given to files not in the sub-tree specified in the root directory
option, including some files needed for complete operation of the
server. To maintain full operability of the server you will need to
mirror some system files into the root directory tree. In
particular you will need to mirror /etc/passwd (or a subset of it),
and any binaries or configuration files needed for printing (if
required). The set of files that must be mirrored is operating
system dependent.

Default: root directory =

Example: root directory = /homes/smb

root postexec (S)

This is the same as the postexec parameter except that the command
is run as root. This is useful for unmounting filesystems (such as
CDROMs) after a connection is closed.

Default: root postexec =

root preexec (S)

This is the same as the preexec parameter except that the command
is run as root. This is useful for mounting filesystems (such as
CDROMs) when a connection is opened.

Default: root preexec =

root preexec close (S)

This is the same as the preexec close parameter except that the
command is run as root.

Default: root preexec close = no

rpc big endian (G)

Setting this option will force the RPC client and server to
transfer data in big endian.

If it is disabled, data will be transferred in little endian.

The behaviour is independent of the endianness of the host machine.

Default: rpc big endian = no

rpc server dynamic port range (G)

This parameter tells the RPC server which port range it is allowed
to use to create a listening socket for LSA, SAM, Netlogon and
others without wellknown tcp ports. The first value is the lowest
number of the port range and the second the highest.

This applies to RPC servers in all server roles.

Default: rpc server dynamic port range = 49152-65535

rpc server port (G)

Specifies which port the server should listen on for DCE/RPC over
TCP/IP traffic.

This controls the default port for all protocols, except for
NETLOGON.

If unset, the first available port from rpc server dynamic port
range is used, e.g. 49152.

The NETLOGON server will use the next available port, e.g. 49153.
To change this port use (eg) rpc server port:netlogon = 4000.

Furthermore, all RPC servers can have the port they use specified
independenty, with (for example) rpc server port:drsuapi = 5000.

This option applies currently only when samba(8) runs as an active
directory domain controller.

The default value 0 causes Samba to select the first available port
from rpc server dynamic port range.

Default: rpc server port = 0

rpc start on demand helpers (G)

This global parameter determines if samba-dcerpcd should be started
on demand to service named pipe (np) DCE-RPC requests from smbd or
winbindd. This is the normal case where no startup scripts have
been modified to start samba-dcerpcd as a daemon.

If samba-dcerpcd is started as a daemon or via a system service
manager such as systemd, this parameter MUST be set to "no",
otherwise samba-dcerpcd will fail to start.

Default: rpc start on demand helpers = yes

samba kcc command (G)

This option specifies the path to the Samba KCC command. This
script is used for replication topology replication.

It should not be necessary to modify this option except for testing
purposes or if the samba_kcc was installed in a non-default
location.

Default: samba kcc command = ${prefix}/sbin/samba_kcc

Example: samba kcc command = /usr/local/bin/kcc

security (G)

This option affects how clients respond to Samba and is one of the
most important settings in the smb.conf file.

Unless server role is specified, the default is security = user, as
this is the most common setting, used for a standalone file server
or a DC.

The alternatives to security = user are security = ads or security
= domain, which support joining Samba to a Windows domain

You should use security = user and map to guest if you want to
mainly setup shares without a password (guest shares). This is
commonly used for a shared printer server.

The different settings will now be explained.

SECURITY = AUTO

This is the default security setting in Samba, and causes Samba to
consult the server role parameter (if set) to determine the
security mode.

SECURITY = USER

If server role is not specified, this is the default security
setting in Samba. With user-level security a client must first
"log-on" with a valid username and password (which can be mapped
using the username map parameter). Encrypted passwords (see the
encrypt passwords parameter) can also be used in this security
mode. Parameters such as force user and guest only if set are then
applied and may change the UNIX user to use on this connection, but
only after the user has been successfully authenticated.

Note that the name of the resource being requested is not sent to
the server until after the server has successfully authenticated
the client. This is why guest shares don't work in user level
security without allowing the server to automatically map unknown
users into the guest account. See the map to guest parameter for
details on doing this.

SECURITY = DOMAIN

This mode will only work correctly if net(8) has been used to add
this machine into a Windows NT Domain. It expects the encrypt
passwords parameter to be set to yes. In this mode Samba will try
to validate the username/password by passing it to a Windows NT
Primary or Backup Domain Controller, in exactly the same way that a
Windows NT Server would do.

Note that a valid UNIX user must still exist as well as the account
on the Domain Controller to allow Samba to have a valid UNIX
account to map file access to.

Note that from the client's point of view security = domain is the
same as security = user. It only affects how the server deals with
the authentication, it does not in any way affect what the client
sees.

See also the password server parameter and the encrypt passwords
parameter.

SECURITY = ADS

In this mode, Samba will act as a domain member in an ADS realm. To
operate in this mode, the machine running Samba will need to have
Kerberos installed and configured and Samba will need to be joined
to the ADS realm using the net utility.

Note that this mode does NOT make Samba operate as a Active
Directory Domain Controller.

Note that this forces require strong key = yes and client schannel
= yes for the primary domain.

Read the chapter about Domain Membership in the HOWTO for details.

Default: security = AUTO

Example: security = DOMAIN

security mask (S)

This parameter has been removed for Samba 4.0.0.

No default

server addresses (S)

This is a per-share parameter to limit share visibility and
accessibility to specific server IP addresses. Multi-homed servers
can offer a different set of shares per interface.

An empty list means to offer a share on all interfaces.

Default: server addresses =

max protocol

This parameter is a synonym for server max protocol.

protocol

This parameter is a synonym for server max protocol.

server max protocol (G)

The value of the parameter (a string) is the highest protocol level
that will be supported by the server.

Possible values are :

o LANMAN1: First modern version of the protocol. Long
filename support.

o LANMAN2: Updates to Lanman1 protocol.

o NT1: Current up to date version of the protocol. Used by
Windows NT. Known as CIFS.

o SMB2: Re-implementation of the SMB protocol. Used by
Windows Vista and later versions of Windows. SMB2 has
sub protocols available.

o SMB2_02: The earliest SMB2 version.

o SMB2_10: Windows 7 SMB2 version.

By default SMB2 selects the SMB2_10 variant.

o SMB3: The same as SMB2. Used by Windows 8. SMB3 has sub
protocols available.

o SMB3_00: Windows 8 SMB3 version.

o SMB3_02: Windows 8.1 SMB3 version.

o SMB3_11: Windows 10 SMB3 version.

By default SMB3 selects the SMB3_11 variant.

Normally this option should not be set as the automatic negotiation
phase in the SMB protocol takes care of choosing the appropriate
protocol.

Default: server max protocol = SMB3

Example: server max protocol = LANMAN1

min protocol

This parameter is a synonym for server min protocol.

server min protocol (G)

This setting controls the minimum protocol version that the server
will allow the client to use.

Normally this option should not be set as the automatic negotiation
phase in the SMB protocol takes care of choosing the appropriate
protocol unless you have legacy clients which are SMB1 capable
only.

See Related command: server max protocol for a full list of
available protocols.

Default: server min protocol = SMB2_02

Example: server min protocol = NT1

server multi channel support (G)

This boolean parameter controls whether smbd(8) will support SMB3
multi-channel.

This parameter was added with version 4.4.

Note that this feature was still considered experimental up to
4.14.

Due to dependencies to kernel APIs of Linux or FreeBSD, it's only
possible to use this feature on Linux and FreeBSD for now. For
testing this restriction can be overwritten by specifying
force:server multi channel support=yes in addition.

This option is enabled by default starting with to 4.15 (on Linux
and FreeBSD).

Default: server multi channel support = yes

server role (G)

This option determines the basic operating mode of a Samba server
and is one of the most important settings in the smb.conf file.

The default is server role = auto, as causes Samba to operate
according to the security setting, or if not specified as a simple
file server that is not connected to any domain.

The alternatives are server role = standalone or server role =
member server, which support joining Samba to a Windows domain,
along with server role = domain controller, which run Samba as a
Windows domain controller.

You should use server role = standalone and map to guest if you
want to mainly setup shares without a password (guest shares). This
is commonly used for a shared printer server.

SERVER ROLE = AUTO

This is the default server role in Samba, and causes Samba to
consult the security parameter (if set) to determine the server
role, giving compatible behaviours to previous Samba versions.

SERVER ROLE = STANDALONE

If security is also not specified, this is the default security
setting in Samba. In standalone operation, a client must first
"log-on" with a valid username and password (which can be mapped
using the username map parameter) stored on this machine. Encrypted
passwords (see the encrypt passwords parameter) are by default used
in this security mode. Parameters such as force user and guest only
if set are then applied and may change the UNIX user to use on this
connection, but only after the user has been successfully
authenticated.

SERVER ROLE = MEMBER SERVER

This mode will only work correctly if net(8) has been used to add
this machine into a Windows Domain. It expects the encrypt
passwords parameter to be set to yes. In this mode Samba will try
to validate the username/password by passing it to a Windows or
Samba Domain Controller, in exactly the same way that a Windows
Server would do.

Note that a valid UNIX user must still exist as well as the account
on the Domain Controller to allow Samba to have a valid UNIX
account to map file access to. Winbind can provide this.

SERVER ROLE = CLASSIC PRIMARY DOMAIN CONTROLLER

This mode of operation runs a classic Samba primary domain
controller, providing domain logon services to Windows and Samba
clients of an NT4-like domain. Clients must be joined to the domain
to create a secure, trusted path across the network. There must be
only one PDC per NetBIOS scope (typically a broadcast network or
clients served by a single WINS server).

SERVER ROLE = CLASSIC BACKUP DOMAIN CONTROLLER

This mode of operation runs a classic Samba backup domain
controller, providing domain logon services to Windows and Samba
clients of an NT4-like domain. As a BDC, this allows multiple Samba
servers to provide redundant logon services to a single NetBIOS
scope.

SERVER ROLE = ACTIVE DIRECTORY DOMAIN CONTROLLER

This mode of operation runs Samba as an active directory domain
controller, providing domain logon services to Windows and Samba
clients of the domain. This role requires special configuration,
see the Samba4 HOWTO

SERVER ROLE = IPA DOMAIN CONTROLLER

This mode of operation runs Samba in a hybrid mode for IPA domain
controller, providing forest trust to Active Directory. This role
requires special configuration performed by IPA installers and
should not be used manually by any administrator.

Default: server role = AUTO

Example: server role = ACTIVE DIRECTORY DOMAIN CONTROLLER

server schannel (G)

This option is deprecated and will be removed in future, as it is a
security problem if not set to "yes" (which will be the hardcoded
behavior in future).

Avoid using this option! Use explicit 'server require
schannel:COMPUTERACCOUNT = no' instead!

Samba will log an error in the log files at log level 0 if legacy a
client is rejected or allowed without an explicit, 'server require
schannel:COMPUTERACCOUNT = no' option for the client. The message
will indicate the explicit 'server require schannel:COMPUTERACCOUNT
= no' line to be added, if the legacy client software requires it.
(The log level can be adjusted with
'CVE_2020_1472:error_debug_level = 1' in order to complain only at
a higher log level).

This allows admins to use "auto" only for a short grace period, in
order to collect the explicit 'server require
schannel:COMPUTERACCOUNT = no' options.

See CVE-2020-1472(ZeroLogon),
https://bugzilla.samba.org/show_bug.cgi?id=14497.

This option is over-ridden by the server require
schannel:COMPUTERACCOUNT option.

This option is over-ridden by the effective value of 'yes' from the
'server schannel require seal:COMPUTERACCOUNT' and/or 'server
schannel require seal' options.

Default: server schannel = yes

server require schannel:COMPUTERACCOUNT (G)

If you still have legacy domain members, which required "server
schannel = auto" before, it is possible to specify explicit
exception per computer account by using 'server require
schannel:COMPUTERACCOUNT = no' as option. Note that COMPUTERACCOUNT
has to be the sAMAccountName value of the computer account
(including the trailing '$' sign).

Samba will complain in the log files at log level 0, about the
security problem if the option is not set to "no", but the related
computer is actually using the netlogon secure channel (schannel)
feature. (The log level can be adjusted with
'CVE_2020_1472:warn_about_unused_debug_level = 1' in order to
complain only at a higher log level).

Samba will warn in the log files at log level 5, if a setting is
still needed for the specified computer account.

See CVE-2020-1472(ZeroLogon),
https://bugzilla.samba.org/show_bug.cgi?id=14497.

This option overrides the server schannel option.

This option is over-ridden by the effective value of 'yes' from the
'server schannel require seal:COMPUTERACCOUNT' and/or 'server
schannel require seal' options.

Which means 'server require schannel:COMPUTERACCOUNT = no' is only
useful in combination with 'server schannel require
seal:COMPUTERACCOUNT = no'

server require schannel:LEGACYCOMPUTER1$ = no
server require schannel seal:LEGACYCOMPUTER1$ = no
server require schannel:NASBOX$ = no
server require schannel seal:NASBOX$ = no
server require schannel:LEGACYCOMPUTER2$ = no
server require schannel seal:LEGACYCOMPUTER2$ = no

No default

server schannel require seal (G)

This option is deprecated and will be removed in future, as it is a
security problem if not set to "yes" (which will be the hardcoded
behavior in future).

This option controls whether the netlogon server, will reject the
usage of netlogon secure channel without privacy/enryption.

The option is modelled after the registry key available on Windows.

HKEY_LOCAL_MACHINE\SYSTEM\CurrentControlSet\Services\Netlogon\Parameters\RequireSeal=2

Avoid using this option! Use the per computer account specific
option 'server schannel require seal:COMPUTERACCOUNT' instead!
Which is available with the patches for CVE-2022-38023 see
https://bugzilla.samba.org/show_bug.cgi?id=15240.

Samba will log an error in the log files at log level 0 if legacy a
client is rejected or allowed without an explicit, 'server schannel
require seal:COMPUTERACCOUNT = no' option for the client. The
message will indicate the explicit 'server schannel require
seal:COMPUTERACCOUNT = no' line to be added, if the legacy client
software requires it. (The log level can be adjusted with
'CVE_2022_38023:error_debug_level = 1' in order to complain only at
a higher log level).

This allows admins to use "no" only for a short grace period, in
order to collect the explicit 'server schannel require
seal:COMPUTERACCOUNT = no' options.

When set to 'yes' this option overrides the 'server require
schannel:COMPUTERACCOUNT' and 'server schannel' options and implies
'server require schannel:COMPUTERACCOUNT = yes'.

This option is over-ridden by the server schannel require
seal:COMPUTERACCOUNT option.

Default: server schannel require seal = yes

server schannel require seal:COMPUTERACCOUNT (G)

If you still have legacy domain members, which required "server
schannel require seal = no" before, it is possible to specify
explicit exception per computer account by using 'server schannel
require seal:COMPUTERACCOUNT = no' as option. Note that
COMPUTERACCOUNT has to be the sAMAccountName value of the computer
account (including the trailing '$' sign).

Samba will warn in the log files at log level 5, if a setting is
still needed for the specified computer account.

See CVE-2022-38023,
https://bugzilla.samba.org/show_bug.cgi?id=15240.

This option overrides the 'server schannel require seal' option.

When set to 'yes' this option overrides the 'server require
schannel:COMPUTERACCOUNT' and 'server schannel' options and implies
'server require schannel:COMPUTERACCOUNT = yes'.

server require schannel seal:LEGACYCOMPUTER1$ = no
server require schannel seal:NASBOX$ = no
server require schannel seal:LEGACYCOMPUTER2$ = no

No default

server services (G)

This option contains the services that the Samba daemon will run.

An entry in the smb.conf file can either override the previous
value completely or entries can be removed from or added to it by
prefixing them with + or -.

Default: server services = s3fs, rpc, nbt, wrepl, ldap, cldap, kdc,
drepl, winbindd, ntp_signd, kcc, dnsupdate, dns

Example: server services = -s3fs, +smb

server signing (G)

This controls whether the client is allowed or required to use SMB1
and SMB2 signing. Possible values are default, auto, mandatory and
disabled.

By default, and when smb signing is set to default, smb signing is
required when server role is active directory domain controller and
disabled otherwise.

When set to auto, SMB1 signing is offered, but not enforced. When
set to mandatory, SMB1 signing is required and if set to disabled,
SMB signing is not offered either.

For the SMB2 protocol, by design, signing cannot be disabled. In
the case where SMB2 is negotiated, if this parameter is set to
disabled, it will be treated as auto. Setting it to mandatory will
still require SMB2 clients to use signing.

Default: server signing = default

server smb encrypt (S)

This parameter controls whether a remote client is allowed or
required to use SMB encryption. It has different effects depending
on whether the connection uses SMB1 or SMB2 and newer:

o If the connection uses SMB1, then this option controls
the use of a Samba-specific extension to the SMB
protocol introduced in Samba 3.2 that makes use of the
Unix extensions.

o If the connection uses SMB2 or newer, then this option
controls the use of the SMB-level encryption that is
supported in SMB version 3.0 and above and available in
Windows 8 and newer.

This parameter can be set globally and on a per-share bases.
Possible values are off, if_required, desired, and required. A
special value is default which is the implicit default setting of
if_required.

This may be set on a per-share basis, but clients may chose to
encrypt the entire session, not just traffic to a specific
share. If this is set to mandatory then all traffic to a share
must be encrypted once the connection has been made to the
share. The server would return "access denied" to all
non-encrypted requests on such a share. Selecting encrypted
traffic reduces throughput as smaller packet sizes must be used
(no huge UNIX style read/writes allowed) as well as the
overhead of encrypting and signing all the data.

If SMB encryption is selected, Windows style SMB signing (see
the server signing option) is no longer necessary, as the
GSSAPI flags use select both signing and sealing of the data.

When set to auto or default, SMB encryption is offered, but not
enforced. When set to mandatory, SMB encryption is required and
if set to disabled, SMB encryption can not be negotiated.

Effects for SMB2 and newer
Native SMB transport encryption is available in SMB version 3.0
or newer. It is only offered by Samba if server max protocol is
set to SMB3 or newer. Clients supporting this type of
encryption include Windows 8 and newer, Windows server 2012 and
newer, and smbclient of Samba 4.1 and newer.

The protocol implementation offers various options:

o The capability to perform SMB encryption can be
negotiated during protocol negotiation.

o Data encryption can be enabled globally. In that
case, an encryption-capable connection will have all
traffic in all its sessions encrypted. In particular
all share connections will be encrypted.

o Data encryption can also be enabled per share if not
enabled globally. For an encryption-capable
connection, all connections to an encryption-enabled
share will be encrypted.

o Encryption can be enforced. This means that session
setups will be denied on non-encryption-capable
connections if data encryption has been enabled
globally. And tree connections will be denied for
non-encryption capable connections to shares with
data encryption enabled.

These features can be controlled with settings of server smb
encrypt as follows:

o Leaving it as default, explicitly setting default,
or setting it to if_required globally will enable
negotiation of encryption but will not turn on data
encryption globally or per share.

o Setting it to desired globally will enable
negotiation and will turn on data encryption on
sessions and share connections for those clients
that support it.

o Setting it to required globally will enable
negotiation and turn on data encryption on sessions
and share connections. Clients that do not support
encryption will be denied access to the server.

o Setting it to off globally will completely disable
the encryption feature for all connections. Setting
server smb encrypt = required for individual shares
(while it's globally off) will deny access to this
shares for all clients.

o Setting it to desired on a share will turn on data
encryption for this share for clients that support
encryption if negotiation has been enabled globally.

o Setting it to required on a share will enforce data
encryption for this share if negotiation has been
enabled globally. I.e. clients that do not support
encryption will be denied access to the share.

Note that this allows per-share enforcing to be
controlled in Samba differently from Windows: In
Windows, RejectUnencryptedAccess is a global
setting, and if it is set, all shares with data
encryption turned on are automatically enforcing
encryption. In order to achieve the same effect in
Samba, one has to globally set server smb encrypt to
if_required, and then set all shares that should be
encrypted to required. Additionally, it is possible
in Samba to have some shares with encryption
required and some other shares with encryption only
desired, which is not possible in Windows.

o Setting it to off or if_required for a share has no
effect.

Default: server smb encrypt = default

server smb3 encryption algorithms (G)

This parameter specifies the availability and order of encryption
algorithms which are available for negotiation in the SMB3_11
dialect.

It is also possible to remove individual algorithms from the
default list, by prefixing them with '-'. This can avoid having to
specify a hardcoded list.

Note: that the removal of AES-128-CCM from the list will result in
SMB3_00 and SMB3_02 being unavailable, as it is the default and
only available algorithm for these dialects.

Default: server smb3 encryption algorithms = AES-128-GCM,
AES-128-CCM, AES-256-GCM, AES-256-CCM

Example: server smb3 encryption algorithms = AES-256-GCM

Example: server smb3 encryption algorithms = -AES-128-GCM
-AES-128-CCM

server smb3 signing algorithms (G)

This parameter specifies the availability and order of signing
algorithms which are available for negotiation in the SMB3_11
dialect.

It is also possible to remove individual algorithms from the
default list, by prefixing them with '-'. This can avoid having to
specify a hardcoded list.

Default: server smb3 signing algorithms = AES-128-GMAC,
AES-128-CMAC, HMAC-SHA256

Example: server smb3 signing algorithms = AES-128-CMAC, HMAC-SHA256

Example: server smb3 signing algorithms = -AES-128-CMAC

server string (G)

This controls what string will show up in the printer comment box
in print manager and next to the IPC connection in net view. It can
be any string that you wish to show to your users.

It also sets what will appear in browse lists next to the machine
name.

A %v will be replaced with the Samba version number.

A %h will be replaced with the hostname.

Default: server string = Samba %v

Example: server string = University of GNUs Samba Server

set primary group script (G)

Thanks to the Posix subsystem in NT a Windows User has a primary
group in addition to the auxiliary groups. This script sets the
primary group in the unix user database when an administrator sets
the primary group from the windows user manager or when fetching a
SAM with net rpc vampire. %u will be replaced with the user whose
primary group is to be set. %g will be replaced with the group to
set.

Default: set primary group script =

Example: set primary group script = /usr/sbin/usermod -g '%g' '%u'

set quota command (G)

The set quota command should only be used whenever there is no
operating system API available from the OS that samba can use.

This option is only available if Samba was compiled with quota
support.

This parameter should specify the path to a script that can set
quota for the specified arguments.

The specified script should take the following arguments:

o 1 - path to where the quota needs to be set. This needs
to be interpreted relative to the current working
directory that the script may also check for.

o 2 - quota type

o 1 - user quotas

o 2 - user default quotas (uid = -1)

o 3 - group quotas

o 4 - group default quotas (gid = -1)

o 3 - id (uid for user, gid for group, -1 if N/A)

o 4 - quota state (0 = disable, 1 = enable, 2 = enable and
enforce)

o 5 - block softlimit

o 6 - block hardlimit

o 7 - inode softlimit

o 8 - inode hardlimit

o 9(optional) - block size, defaults to 1024

The script should output at least one line of data on success. And
nothing on failure.

Default: set quota command =

Example: set quota command = /usr/local/sbin/set_quota

share:fake_fscaps (G)

This is needed to support some special application that makes
QFSINFO calls to check whether we set the SPARSE_FILES bit (0x40).
If this bit is not set that particular application refuses to work
against Samba. With share:fake_fscaps = 64 the SPARSE_FILES file
system capability flag is set. Use other decimal values to specify
the bitmask you need to fake.

Default: share:fake_fscaps = 0

short preserve case (S)

This boolean parameter controls if new files which conform to 8.3
syntax, that is all in upper case and of suitable length, are
created upper case, or if they are forced to be the default case.
This option can be use with preserve case = yes to permit long
filenames to retain their case, while short names are lowered.

See the section on NAME MANGLING.

Default: short preserve case = yes

show add printer wizard (G)

With the introduction of MS-RPC based printing support for Windows
NT/2000 client in Samba 2.2, a "Printers..." folder will appear on
Samba hosts in the share listing. Normally this folder will contain
an icon for the MS Add Printer Wizard (APW). However, it is
possible to disable this feature regardless of the level of
privilege of the connected user.

Under normal circumstances, the Windows NT/2000 client will open a
handle on the printer server with OpenPrinterEx() asking for
Administrator privileges. If the user does not have administrative
access on the print server (i.e is not root or has granted the
SePrintOperatorPrivilege), the OpenPrinterEx() call fails and the
client makes another open call with a request for a lower privilege
level. This should succeed, however the APW icon will not be
displayed.

Disabling the show add printer wizard parameter will always cause
the OpenPrinterEx() on the server to fail. Thus the APW icon will
never be displayed.

Note
This does not prevent the same user from having administrative
privilege on an individual printer.
Default: show add printer wizard = yes

shutdown script (G)

This a full path name to a script called by smbd(8) that should
start a shutdown procedure.

If the connected user possesses the SeRemoteShutdownPrivilege,
right, this command will be run as root.

The %z %t %r %f variables are expanded as follows:

o %z will be substituted with the shutdown message sent to
the server.

o %t will be substituted with the number of seconds to
wait before effectively starting the shutdown procedure.

o %r will be substituted with the switch -r. It means
reboot after shutdown for NT.

o %f will be substituted with the switch -f. It means
force the shutdown even if applications do not respond
for NT.

Shutdown script example:

#!/bin/bash

time=$2
let time="${time} / 60"
let time="${time} + 1"

/sbin/shutdown $3 $4 +$time $1 &

Shutdown does not return so we need to launch it in background.

Default: shutdown script =

Example: shutdown script = /usr/local/samba/sbin/shutdown %m %t %r
%f

unix extensions

This parameter is a synonym for smb1 unix extensions.

smb1 unix extensions (G)

This boolean parameter controls whether Samba implements the
SMB1/CIFS UNIX extensions, as defined by HP. These extensions
enable Samba to better serve UNIX SMB1/CIFS clients by supporting
features such as symbolic links, hard links, etc... These
extensions require a similarly enabled client, and are of no
current use to Windows clients.

Note if this parameter is turned on, the wide links parameter will
automatically be disabled.

See the parameter allow insecure wide links if you wish to change
this coupling between the two parameters.

Default: smb1 unix extensions = yes

smb2 disable lock sequence checking (G)

This boolean parameter controls whether smbd(8) will disable lock
sequence checking even for multi-channel connections as well as
durable handles.

The [MS-SMB2] specification (under 3.3.5.14 Receiving an SMB2 LOCK
Request) documents that a server should do lock sequence if
Open.IsResilient or Open.IsDurable or Open.IsPersistent is TRUE or
if Connection.Dialect belongs to the SMB 3.x dialect family and
Connection.ServerCapabilities includes
SMB2_GLOBAL_CAP_MULTI_CHANNEL.

But Windows Server (at least up to v2004) only does these checks
for the Open.IsResilient and Open.IsPersistent. That means they do
not implement the behavior specified in [MS-SMB2].

By default Samba behaves according to the specification and
implements lock sequence checking when multi-channel is used.

Warning: Only enable this option if existing clients can't handle
lock sequence checking for handles without Open.IsResilient and
Open.IsPersistent. And it turns out that the Windows Server
behavior is required.

Note: it's likely that this option will be removed again if future
Windows versions change their behavior.

Note: Samba does not implement Open.IsResilient and
Open.IsPersistent yet.

Default: smb2 disable lock sequence checking = no

Example: smb2 disable lock sequence checking = yes

smb2 disable oplock break retry (G)

This boolean parameter controls whether smbd(8) will trigger smb2
oplock break notification retries when using server multi channel
support = yes.

The [MS-SMB2] specification documents that a server should send
smb2 oplock break notification retries on all available channel to
the given client.

But Windows Server versions (at least up to 2019) do not send smb2
oplock break notification retries on channel failures. That means
they do not implement the behavior specified in [MS-SMB2].

By default Samba behaves according to the specification and send
smb2 oplock break notification retries.

Warning: Only enable this option if existing clients can't handle
possible retries and it turns out that the Windows Server behavior
is required.

Note: it's likely that this option gets removed again if future
Windows versions change their behavior.

Note: this only applies to oplocks and not SMB2 leases.

Default: smb2 disable oplock break retry = no

Example: smb2 disable oplock break retry = yes

smb2 leases (G)

This boolean option tells smbd whether to globally negotiate SMB2
leases on file open requests. Leasing is an SMB2-only feature which
allows clients to aggressively cache files locally above and beyond
the caching allowed by SMB1 oplocks.

This is only available with oplocks = yes and kernel oplocks = no.

Default: smb2 leases = yes

smb2 max credits (G)

This option controls the maximum number of outstanding simultaneous
SMB2 operations that Samba tells the client it will allow. This is
similar to the max mux parameter for SMB1. You should never need to
set this parameter.

The default is 8192 credits, which is the same as a Windows 2008R2
SMB2 server.

Default: smb2 max credits = 8192

smb2 max read (G)

This option specifies the protocol value that smbd(8) will return
to a client, informing the client of the largest size that may be
returned by a single SMB2 read call.

The maximum is 8388608 bytes (8MiB), which is the same as a Windows
Server 2012 r2.

Please note that the default is 8MiB, but it's limit is based on
the smb2 dialect (64KiB for SMB == 2.0, 8MiB for SMB >= 2.1 with
LargeMTU). Large MTU is not supported over NBT (tcp port 139).

Default: smb2 max read = 8388608

smb2 max trans (G)

This option specifies the protocol value that smbd(8) will return
to a client, informing the client of the largest size of buffer
that may be used in querying file meta-data via QUERY_INFO and
related SMB2 calls.

The maximum is 8388608 bytes (8MiB), which is the same as a Windows
Server 2012 r2.

Please note that the default is 8MiB, but it's limit is based on
the smb2 dialect (64KiB for SMB == 2.0, 1MiB for SMB >= 2.1 with
LargeMTU). Large MTU is not supported over NBT (tcp port 139).

Default: smb2 max trans = 8388608

smb2 max write (G)

This option specifies the protocol value that smbd(8) will return
to a client, informing the client of the largest size that may be
sent to the server by a single SMB2 write call.

The maximum is 8388608 bytes (8MiB), which is the same as a Windows
Server 2012 r2.

Please note that the default is 8MiB, but it's limit is based on
the smb2 dialect (64KiB for SMB == 2.0, 8MiB for SMB => 2.1 with
LargeMTU). Large MTU is not supported over NBT (tcp port 139).

Default: smb2 max write = 8388608

smb3 unix extensions (G)

Incomplete SMB 3.11 Unix Extensions. This is only available if
Samba is compiled in DEVELOPER mode.

Default: smb3 unix extensions = no

smbd async dosmode (S)

This parameter control whether the fileserver will use sync or
async methods for fetching the DOS attributes when doing a
directory listing. By default sync methods will be used.

Default: smbd async dosmode = no

smbd getinfo ask sharemode (S)

This parameter allows disabling fetching file write time from the
open file handle database locking.tdb when a client requests file
or directory metadata. It's a performance optimisation at the
expense of protocol correctness.

Default: smbd getinfo ask sharemode = yes

smbd max async dosmode (S)

This parameter controls how many async operations to fetch the DOS
attributes the fileserver will queue when doing directory listings.

Default: smbd max async dosmode = aio max threads * 2

smbd max xattr size (S)

This parameter controls the maximum size of extended attributes
that may be written to the server as EAs or as alternate data
streams if vfs_streams_xattr is enabled. The maximum size of
extended attributes depends on the Samba server's operating system
and the underlying filesystem. The Linux VFS currently sets an
upper boundary of 64 KiB per extended attribute. FreeBSD does not
set a practical upper limit, but since pread() and pwrite() are not
possible via the extattr on FreeBSD, it is not recommended to
increase this value above a few MiB. If a client attempts to write
an overly-large alternate datastream, the Samba server will return
STATUS_FILESYSTEM_LIMITATION. If this error is encountered, users
may try increasing the maximum size supported for xattr writes. If
this is not possible, and writes are from a MacOS client and to an
AFP_Resource extended attribute, the user may enable the vfs_fruit
module and configure to allow stream writes for AFP_Resource to an
alternative storage location. See vfs_fruit documentation for
further details.

Default: smbd max xattr size = 65536

smbd profiling level (G)

This parameter allows the administrator to enable profiling
support.

Possible values are off, count and on.

Default: smbd profiling level = off

Example: smbd profiling level = on

smbd search ask sharemode (S)

This parameter allows disabling fetching file write time from the
open file handle database locking.tdb. It's a performance
optimisation at the expense of protocol correctness.

Default: smbd search ask sharemode = yes

smb encrypt (S)

This is a synonym for server smb encrypt.

Default: smb encrypt = default

smb passwd file (G)

This option sets the path to the encrypted smbpasswd file. By
default the path to the smbpasswd file is compiled into Samba.

An example of use is:

smb passwd file = /etc/samba/smbpasswd

Default: smb passwd file = ${prefix}/private/smbpasswd

smb ports (G)

Specifies which ports the server should listen on for SMB traffic.

Default: smb ports = 445 139

socket options (G)

Warning
Modern server operating systems are tuned for high network
performance in the majority of situations; when you set socket
options you are overriding those settings. Linux in particular
has an auto-tuning mechanism for buffer sizes that will be
disabled if you specify a socket buffer size. This can
potentially cripple your TCP/IP stack.

Getting the socket options correct can make a big difference to
your performance, but getting them wrong can degrade it by just
as much. As with any other low level setting, if you must make
changes to it, make small changes and test the effect before
making any large changes.

This option allows you to set socket options to be used when
talking with the client.

Socket options are controls on the networking layer of the
operating systems which allow the connection to be tuned.

This option will typically be used to tune your Samba server for
optimal performance for your local network. There is no way that
Samba can know what the optimal parameters are for your net, so you
must experiment and choose them yourself. We strongly suggest you
read the appropriate documentation for your operating system first
(perhaps man setsockopt will help).

You may find that on some systems Samba will say "Unknown socket
option" when you supply an option. This means you either
incorrectly typed it or you need to add an include file to
includes.h for your OS. If the latter is the case please send the
patch to samba-technical@lists.samba.org.

Any of the supported socket options may be combined in any way you
like, as long as your OS allows it.

This is the list of socket options currently settable using this
option:

o SO_KEEPALIVE

o SO_REUSEADDR

o SO_BROADCAST

o TCP_NODELAY

o TCP_KEEPCNT *

o TCP_KEEPIDLE *

o TCP_KEEPINTVL *

o IPTOS_LOWDELAY

o IPTOS_THROUGHPUT

o SO_REUSEPORT

o SO_SNDBUF *

o SO_RCVBUF *

o SO_SNDLOWAT *

o SO_RCVLOWAT *

o SO_SNDTIMEO *

o SO_RCVTIMEO *

o TCP_FASTACK *

o TCP_QUICKACK

o TCP_NODELAYACK

o TCP_KEEPALIVE_THRESHOLD *

o TCP_KEEPALIVE_ABORT_THRESHOLD *

o TCP_DEFER_ACCEPT *

o TCP_USER_TIMEOUT *

Those marked with a '*' take an integer argument. The others can
optionally take a 1 or 0 argument to enable or disable the option,
by default they will be enabled if you don't specify 1 or 0.

To specify an argument use the syntax SOME_OPTION = VALUE for
example SO_SNDBUF = 8192. Note that you must not have any spaces
before or after the = sign.

If you are on a local network then a sensible option might be:

socket options = IPTOS_LOWDELAY

If you have a local network then you could try:

socket options = IPTOS_LOWDELAY TCP_NODELAY

If you are on a wide area network then perhaps try setting
IPTOS_THROUGHPUT.

Note that several of the options may cause your Samba server to
fail completely. Use these options with caution!

Default: socket options = TCP_NODELAY

Example: socket options = IPTOS_LOWDELAY

spn update command (G)

This option sets the command that for updating servicePrincipalName
names from spn_update_list.

Default: spn update command = ${prefix}/sbin/samba_spnupdate

Example: spn update command = /usr/local/sbin/spnupdate

spoolss: architecture (G)

Windows spoolss print clients only allow association of server-side
drivers with printers when the driver architecture matches the
advertised print server architecture. Samba's spoolss print server
architecture can be changed using this parameter.

Default: spoolss: architecture = Windows x64

Example: spoolss: architecture = Windows NT x86

spoolss: os_major (G)

Windows might require a new os version number. This option allows
to modify the build number. The complete default version number is:
5.0.2195 (Windows 2000). The example is 6.1.7601 (Windows 2008 R2).

Default: spoolss: os_major = 5

Example: spoolss: os_major = 6

spoolss: os_minor (G)

Default: spoolss: os_minor = 0

Example: spoolss: os_minor = 1

spoolss: os_build (G)

Default: spoolss: os_build = 2195

Example: spoolss: os_build = 7601

spoolss_client: os_major (G)

Windows might require a new os version number. This option allows
to modify the build number. The complete default version number is:
6.1.7007 (Windows 7 and Windows Server 2008 R2).

Default: spoolss_client: os_major = 6

spoolss_client: os_minor (G)

Windows might require a new os version number. This option allows
to modify the build number. The complete default version number is:
6.1.7007 (Windows 7 and Windows Server 2008 R2).

Default: spoolss_client: os_minor = 1

spoolss_client: os_build (G)

Windows might require a new os version number. This option allows
to modify the build number. The complete default version number is:
6.1.7007 (Windows 7 and Windows Server 2008 R2).

Default: spoolss_client: os_build = 7007

spotlight (S)

This parameter controls whether Samba allows Spotlight queries on a
share. For controlling indexing of filesystems you also have to use
Tracker's own configuration system.

Spotlight has several prerequisites:

o Samba must be configured and built with Spotlight
support.

o Tracker integration must be setup and the share must be
indexed by Tracker.

For a detailed set of instructions please see
https://wiki.samba.org/index.php/Spotlight.

Default: spotlight = no

spotlight backend (S)

Spotlight search backend. Available backends:

o noindex - a backend that returns no results.

o tracker - Gnome Tracker.

o elasticsearch - a backend that uses JSON and REST over
HTTP(s) to query an Elasticsearch server.

Default: spotlight backend = noindex

stat cache (G)

This parameter determines if smbd(8) will use a cache in order to
speed up case insensitive name mappings. You should never need to
change this parameter.

Default: stat cache = yes

state directory (G)

This option specifies the directory where TDB files containing
important persistent data will be stored.

Default: state directory = ${prefix}/var/locks

Example: state directory = /var/run/samba/locks/state

store dos attributes (S)

If this parameter is set Samba attempts to first read DOS
attributes (SYSTEM, HIDDEN, ARCHIVE or READ-ONLY) from a filesystem
extended attribute, before mapping DOS attributes to UNIX
permission bits (such as occurs with map hidden and map readonly).
When set, DOS attributes will be stored onto an extended attribute
in the UNIX filesystem, associated with the file or directory. When
this parameter is set it will override the parameters map hidden,
map system, map archive and map readonly and they will behave as if
they were set to off. This parameter writes the DOS attributes as a
string into the extended attribute named "user.DOSATTRIB". This
extended attribute is explicitly hidden from smbd clients
requesting an EA list. On Linux the filesystem must have been
mounted with the mount option user_xattr in order for extended
attributes to work, also extended attributes must be compiled into
the Linux kernel. In Samba 3.5.0 and above the "user.DOSATTRIB"
extended attribute has been extended to store the create time for a
file as well as the DOS attributes. This is done in a backwards
compatible way so files created by Samba 3.5.0 and above can still
have the DOS attribute read from this extended attribute by earlier
versions of Samba, but they will not be able to read the create
time stored there. Storing the create time separately from the
normal filesystem meta-data allows Samba to faithfully reproduce
NTFS semantics on top of a POSIX filesystem. The default has
changed to yes in Samba release 4.9.0 and above to allow better
Windows fileserver compatibility in a default install.

Default: store dos attributes = yes

strict allocate (S)

This is a boolean that controls the handling of disk space
allocation in the server. When this is set to yes the server will
change from UNIX behaviour of not committing real disk storage
blocks when a file is extended to the Windows behaviour of actually
forcing the disk system to allocate real storage blocks when a file
is created or extended to be a given size. In UNIX terminology this
means that Samba will stop creating sparse files.

This option is really designed for file systems that support fast
allocation of large numbers of blocks such as extent-based file
systems. On file systems that don't support extents (most notably
ext3) this can make Samba slower. When you work with large files
over >100MB on file systems without extents you may even run into
problems with clients running into timeouts.

When you have an extent based filesystem it's likely that we can
make use of unwritten extents which allows Samba to allocate even
large amounts of space very fast and you will not see any timeout
problems caused by strict allocate. With strict allocate in use you
will also get much better out of quota messages in case you use
quotas. Another advantage of activating this setting is that it
will help to reduce file fragmentation.

To give you an idea on which filesystems this setting might
currently be a good option for you: XFS, ext4, btrfs, ocfs2 on
Linux and JFS2 on AIX support unwritten extents. On Filesystems
that do not support it, preallocation is probably an expensive
operation where you will see reduced performance and risk to let
clients run into timeouts when creating large files. Examples are
ext3, ZFS, HFS+ and most others, so be aware if you activate this
setting on those filesystems.

Default: strict allocate = no

strict locking (S)

This is an enumerated type that controls the handling of file
locking in the server. When this is set to yes, the server will
check every read and write access for file locks, and deny access
if locks exist. This can be slow on some systems.

When strict locking is set to Auto (the default), the server
performs file lock checks only on non-oplocked files. As most
Windows redirectors perform file locking checks locally on oplocked
files this is a good trade off for improved performance.

When strict locking is disabled, the server performs file lock
checks only when the client explicitly asks for them.

Well-behaved clients always ask for lock checks when it is
important. So in the vast majority of cases, strict locking = Auto
or strict locking = no is acceptable.

Default: strict locking = Auto

strict rename (S)

By default a Windows SMB server prevents directory renames when
there are open file or directory handles below it in the filesystem
hierarchy. Historically Samba has always allowed this as POSIX
filesystem semantics require it.

This boolean parameter allows Samba to match the Windows behavior.
Setting this to "yes" is a very expensive change, as it forces
Samba to travers the entire open file handle database on every
directory rename request. In a clustered Samba system the cost is
even greater than the non-clustered case.

When set to "no" smbd only checks the local process the client is
attached to for open files below a directory being renamed, instead
of checking for open files across all smbd processes.

Because of the expense in fully searching the database, the default
is "no", and it is recommended to be left that way unless a
specific Windows application requires it to be changed.

If the client has requested UNIX extensions (POSIX pathnames) then
renames are always allowed and this parameter has no effect.

Default: strict rename = no

strict sync (S)

This parameter controls whether Samba honors a request from an SMB
client to ensure any outstanding operating system buffer contents
held in memory are safely written onto stable storage on disk. If
set to yes, which is the default, then Windows applications can
force the smbd server to synchronize unwritten data onto the disk.
If set to no then smbd will ignore client requests to synchronize
unwritten data onto stable storage on disk.

In Samba 4.7.0, the default for this parameter changed from no to
yes to better match the expectations of SMB2/3 clients and improve
application safety when running against smbd.

The flush request from SMB2/3 clients is handled asynchronously
inside smbd, so leaving the parameter as the default value of yes
does not block the processing of other requests to the smbd
process.

Legacy Windows applications (such as the Windows 98 explorer shell)
seemed to confuse writing buffer contents to the operating system
with synchronously writing outstanding data onto stable storage on
disk. Changing this parameter to no means that smbd(8) will ignore
the Windows applications request to synchronize unwritten data onto
disk. Only consider changing this if smbd is serving obsolete SMB1
Windows clients prior to Windows XP (Windows 98 and below). There
should be no need to change this setting for normal operations.

Default: strict sync = yes

svcctl list (G)

This option defines a list of init scripts that smbd will use for
starting and stopping Unix services via the Win32 ServiceControl
API. This allows Windows administrators to utilize the MS
Management Console plug-ins to manage a Unix server running Samba.

The administrator must create a directory name svcctl in Samba's
$(libdir) and create symbolic links to the init scripts in
/etc/init.d/. The name of the links must match the names given as
part of the svcctl list.

Default: svcctl list =

Example: svcctl list = cups postfix portmap httpd

sync always (S)

This is a boolean parameter that controls whether writes will
always be written to stable storage before the write call returns.
If this is no then the server will be guided by the client's
request in each write call (clients can set a bit indicating that a
particular write should be synchronous). If this is yes then every
write will be followed by a fsync() call to ensure the data is
written to disk. Note that the strict sync parameter must be set to
yes in order for this parameter to have any effect.

Default: sync always = no

syslog (G)

This parameter maps how Samba debug messages are logged onto the
system syslog logging levels. Samba debug level zero maps onto
syslog LOG_ERR, debug level one maps onto LOG_WARNING, debug level
two maps onto LOG_NOTICE, debug level three maps onto LOG_INFO. All
higher levels are mapped to LOG_DEBUG.

This parameter sets the threshold for sending messages to syslog.
Only messages with debug level less than this value will be sent to
syslog. There still will be some logging to log.[sn]mbd even if
syslog only is enabled.

The logging parameter should be used instead. When logging is set,
it overrides the syslog parameter.

Default: syslog = 1

syslog only (G)

If this parameter is set then Samba debug messages are logged into
the system syslog only, and not to the debug log files. There still
will be some logging to log.[sn]mbd even if syslog only is enabled.

The logging parameter should be used instead. When logging is set,
it overrides the syslog only parameter.

Default: syslog only = no

template homedir (G)

When filling out the user information for a Windows NT user, the
winbindd(8) daemon uses this parameter to fill in the home
directory for that user. If the string %D is present it is
substituted with the user's Windows NT domain name. If the string
%U is present it is substituted with the user's Windows NT user
name.

Default: template homedir = /home/%D/%U

template shell (G)

When filling out the user information for a Windows NT user, the
winbindd(8) daemon uses this parameter to fill in the login shell
for that user.

Default: template shell = /bin/false

time server (G)

This parameter determines if nmbd(8) advertises itself as a time
server to Windows clients.

Default: time server = no

debug timestamp

This parameter is a synonym for timestamp logs.

timestamp logs (G)

Samba debug log messages are timestamped by default. If you are
running at a high debug level these timestamps can be distracting.
This boolean parameter allows timestamping to be turned off.

Default: timestamp logs = yes

tls cafile (G)

This option can be set to a file (PEM format) containing CA
certificates of root CAs to trust to sign certificates or
intermediate CA certificates.

This path is relative to private dir if the path does not start
with a /.

Default: tls cafile = tls/ca.pem

tls certfile (G)

This option can be set to a file (PEM format) containing the RSA
certificate.

This path is relative to private dir if the path does not start
with a /.

Default: tls certfile = tls/cert.pem

tls crlfile (G)

This option can be set to a file containing a certificate
revocation list (CRL).

This path is relative to private dir if the path does not start
with a /.

Default: tls crlfile =

tls dh params file (G)

This option can be set to a file with Diffie-Hellman parameters
which will be used with DH ciphers.

This path is relative to private dir if the path does not start
with a /.

Default: tls dh params file =

tls enabled (G)

If this option is set to yes, then Samba will use TLS when possible
in communication.

Default: tls enabled = yes

tls keyfile (G)

This option can be set to a file (PEM format) containing the RSA
private key. This file must be accessible without a pass-phrase,
i.e. it must not be encrypted.

This path is relative to private dir if the path does not start
with a /.

Default: tls keyfile = tls/key.pem

tls priority (G)

This option can be set to a string describing the TLS protocols to
be supported in the parts of Samba that use GnuTLS, specifically
the AD DC.

The string is appended to the default priority list of GnuTLS.

The valid options are described in the GNUTLS Priority-Strings
documentation at
http://gnutls.org/manual/html_node/Priority-Strings.html

The SSL3.0 protocol will be disabled.

Default: tls priority = NORMAL:-VERS-SSL3.0

tls verify peer (G)

This controls if and how strict the client will verify the peer's
certificate and name. Possible values are (in increasing order):
no_check, ca_only, ca_and_name_if_available, ca_and_name and
as_strict_as_possible.

When set to no_check the certificate is not verified at all, which
allows trivial man in the middle attacks.

When set to ca_only the certificate is verified to be signed from a
ca specified in the tls ca file option. Setting tls ca file to a
valid file is required. The certificate lifetime is also verified.
If the tls crl file option is configured, the certificate is also
verified against the ca crl.

When set to ca_and_name_if_available all checks from ca_only are
performed. In addition, the peer hostname is verified against the
certificate's name, if it is provided by the application layer and
not given as an ip address string.

When set to ca_and_name all checks from ca_and_name_if_available
are performed. In addition the peer hostname needs to be provided
and even an ip address is checked against the certificate's name.

When set to as_strict_as_possible all checks from ca_and_name are
performed. In addition the tls crl file needs to be configured.
Future versions of Samba may implement additional checks.

Default: tls verify peer = as_strict_as_possible

unicode (G)

Specifies whether the server and client should support unicode.

If this option is set to false, the use of ASCII will be forced.

Default: unicode = yes

unix charset (G)

Specifies the charset the unix machine Samba runs on uses. Samba
needs to know this in order to be able to convert text to the
charsets other SMB clients use.

This is also the charset Samba will use when specifying arguments
to scripts that it invokes.

Default: unix charset = UTF-8

Example: unix charset = ASCII

unix password sync (G)

This boolean parameter controls whether Samba attempts to
synchronize the UNIX password with the SMB password when the
encrypted SMB password in the smbpasswd file is changed. If this is
set to yes the program specified in the passwd program parameter is
called AS ROOT - to allow the new UNIX password to be set without
access to the old UNIX password (as the SMB password change code
has no access to the old password cleartext, only the new).

This option has no effect if samba is running as an active
directory domain controller, in that case have a look at the
password hash gpg key ids option and the samba-tool user
syncpasswords command.

Default: unix password sync = no

use client driver (S)

This parameter applies only to Windows NT/2000 clients. It has no
effect on Windows 95/98/ME clients. When serving a printer to
Windows NT/2000 clients without first installing a valid printer
driver on the Samba host, the client will be required to install a
local printer driver. From this point on, the client will treat the
print as a local printer and not a network printer connection. This
is much the same behavior that will occur when disable spoolss =
yes.

The differentiating factor is that under normal circumstances, the
NT/2000 client will attempt to open the network printer using
MS-RPC. The problem is that because the client considers the
printer to be local, it will attempt to issue the OpenPrinterEx()
call requesting access rights associated with the logged on user.
If the user possesses local administrator rights but not root
privilege on the Samba host (often the case), the OpenPrinterEx()
call will fail. The result is that the client will now display an
"Access Denied; Unable to connect" message in the printer queue
window (even though jobs may successfully be printed).

If this parameter is enabled for a printer, then any attempt to
open the printer with the PRINTER_ACCESS_ADMINISTER right is mapped
to PRINTER_ACCESS_USE instead. Thus allowing the OpenPrinterEx()
call to succeed. This parameter MUST not be enabled on a print
share which has valid print driver installed on the Samba server.

Default: use client driver = no

use mmap (G)

This global parameter determines if the tdb internals of Samba can
depend on mmap working correctly on the running system. Samba
requires a coherent mmap/read-write system memory cache. Currently
only OpenBSD and HPUX do not have such a coherent cache, and on
those platforms this parameter is overridden internally to be
effectively no. On all systems this parameter should be left alone.
This parameter is provided to help the Samba developers track down
problems with the tdb internal code.

Default: use mmap = yes

username level (G)

This option helps Samba to try and 'guess' at the real UNIX
username, as many DOS clients send an all-uppercase username. By
default Samba tries all lowercase, followed by the username with
the first letter capitalized, and fails if the username is not
found on the UNIX machine.

If this parameter is set to non-zero the behavior changes. This
parameter is a number that specifies the number of uppercase
combinations to try while trying to determine the UNIX user name.
The higher the number the more combinations will be tried, but the
slower the discovery of usernames will be. Use this parameter when
you have strange usernames on your UNIX machine, such as
AstrangeUser .

This parameter is needed only on UNIX systems that have case
sensitive usernames.

Default: username level = 0

Example: username level = 5

username map (G)

This option allows you to specify a file containing a mapping of
usernames from the clients to the server. This can be used for
several purposes. The most common is to map usernames that users
use on DOS or Windows machines to those that the UNIX box uses. The
other is to map multiple users to a single username so that they
can more easily share files.

Please note that for user mode security, the username map is
applied prior to validating the user credentials. Domain member
servers (domain or ads) apply the username map after the user has
been successfully authenticated by the domain controller and
require fully qualified entries in the map table (e.g. biddle =
DOMAIN\foo).

The map file is parsed line by line. Each line should contain a
single UNIX username on the left then a '=' followed by a list of
usernames on the right. The list of usernames on the right may
contain names of the form @group in which case they will match any
UNIX username in that group. The special client name '*' is a
wildcard and matches any name. Each line of the map file may be up
to 1023 characters long.

The file is processed on each line by taking the supplied username
and comparing it with each username on the right hand side of the
'=' signs. If the supplied name matches any of the names on the
right hand side then it is replaced with the name on the left.
Processing then continues with the next line.

If any line begins with a '#' or a ';' then it is ignored.

If any line begins with an '!' then the processing will stop after
that line if a mapping was done by the line. Otherwise mapping
continues with every line being processed. Using '!' is most useful
when you have a wildcard mapping line later in the file.

For example to map from the name admin or administrator to the UNIX
name
root you would use:

root = admin administrator

Or to map anyone in the UNIX group system to the UNIX name sys you
would use:

sys = @system

You can have as many mappings as you like in a username map file.

If your system supports the NIS NETGROUP option then the netgroup
database is checked before the /etc/group database for matching
groups.

You can map Windows usernames that have spaces in them by using
double quotes around the name. For example:

tridge = "Andrew Tridgell"

would map the windows username "Andrew Tridgell" to the unix
username "tridge".

The following example would map mary and fred to the unix user sys,
and map the rest to guest. Note the use of the '!' to tell Samba to
stop processing if it gets a match on that line:

!sys = mary fred
guest = *

Note that the remapping is applied to all occurrences of usernames.
Thus if you connect to \\server\fred and fred is remapped to mary
then you will actually be connecting to \\server\mary and will need
to supply a password suitable for mary not fred. The only exception
to this is the username passed to a Domain Controller (if you have
one). The DC will receive whatever username the client supplies
without modification.

Also note that no reverse mapping is done. The main effect this has
is with printing. Users who have been mapped may have trouble
deleting print jobs as PrintManager under WfWg will think they
don't own the print job.

Samba versions prior to 3.0.8 would only support reading the fully
qualified username (e.g.: DOMAIN\user) from the username map when
performing a kerberos login from a client. However, when looking up
a map entry for a user authenticated by NTLM[SSP], only the login
name would be used for matches. This resulted in inconsistent
behavior sometimes even on the same server.

The following functionality is obeyed in version 3.0.8 and later:

When performing local authentication, the username map is applied
to the login name before attempting to authenticate the connection.

When relying upon a external domain controller for validating
authentication requests, smbd will apply the username map to the
fully qualified username (i.e. DOMAIN\user) only after the user
has been successfully authenticated.

An example of use is:

username map = /usr/local/samba/lib/users.map

Default: username map = # no username map

username map cache time (G)

Mapping usernames with the username map or username map script
features of Samba can be relatively expensive. During login of a
user, the mapping is done several times. In particular, calling the
username map script can slow down logins if external databases have
to be queried from the script being called.

The parameter username map cache time controls a mapping cache. It
specifies the number of seconds a mapping from the username map
file or script is to be efficiently cached. The default of 0 means
no caching is done.

Default: username map cache time = 0

Example: username map cache time = 60

username map script (G)

This script is a mutually exclusive alternative to the username map
parameter. This parameter specifies an external program or script
that must accept a single command line option (the username
transmitted in the authentication request) and return a line on
standard output (the name to which the account should mapped). In
this way, it is possible to store username map tables in an LDAP
directory services.

Default: username map script =

Example: username map script = /etc/samba/scripts/mapusers.sh

usershare allow guests (G)

This parameter controls whether user defined shares are allowed to
be accessed by non-authenticated users or not. It is the equivalent
of allowing people who can create a share the option of setting
guest ok = yes in a share definition. Due to its security sensitive
nature, the default is set to off.

Default: usershare allow guests = no

usershare max shares (G)

This parameter specifies the number of user defined shares that are
allowed to be created by users belonging to the group owning the
usershare directory. If set to zero (the default) user defined
shares are ignored.

Default: usershare max shares = 0

usershare owner only (G)

This parameter controls whether the pathname exported by a user
defined shares must be owned by the user creating the user defined
share or not. If set to True (the default) then smbd checks that
the directory path being shared is owned by the user who owns the
usershare file defining this share and refuses to create the share
if not. If set to False then no such check is performed and any
directory path may be exported regardless of who owns it.

Default: usershare owner only = yes

usershare path (G)

This parameter specifies the absolute path of the directory on the
filesystem used to store the user defined share definition files.
This directory must be owned by root, and have no access for other,
and be writable only by the group owner. In addition the "sticky"
bit must also be set, restricting rename and delete to owners of a
file (in the same way the /tmp directory is usually configured).
Members of the group owner of this directory are the users allowed
to create usershares.

For example, a valid usershare directory might be
/usr/local/samba/lib/usershares, set up as follows.

ls -ld /usr/local/samba/lib/usershares/
drwxrwx--T 2 root power_users 4096 2006-05-05 12:27 /usr/local/samba/lib/usershares/

In this case, only members of the group "power_users" can create
user defined shares.

Default: usershare path = ${prefix}/var/locks/usershares

usershare prefix allow list (G)

This parameter specifies a list of absolute pathnames the root of
which are allowed to be exported by user defined share definitions.
If the pathname to be exported doesn't start with one of the
strings in this list, the user defined share will not be allowed.
This allows the Samba administrator to restrict the directories on
the system that can be exported by user defined shares.

If there is a "usershare prefix deny list" and also a "usershare
prefix allow list" the deny list is processed first, followed by
the allow list, thus leading to the most restrictive
interpretation.

Default: usershare prefix allow list =

Example: usershare prefix allow list = /home /data /space

usershare prefix deny list (G)

This parameter specifies a list of absolute pathnames the root of
which are NOT allowed to be exported by user defined share
definitions. If the pathname exported starts with one of the
strings in this list the user defined share will not be allowed.
Any pathname not starting with one of these strings will be allowed
to be exported as a usershare. This allows the Samba administrator
to restrict the directories on the system that can be exported by
user defined shares.

If there is a "usershare prefix deny list" and also a "usershare
prefix allow list" the deny list is processed first, followed by
the allow list, thus leading to the most restrictive
interpretation.

Default: usershare prefix deny list =

Example: usershare prefix deny list = /etc /dev /private

usershare template share (G)

User defined shares only have limited possible parameters such as
path, guest ok, etc. This parameter allows usershares to "cloned"
from an existing share. If "usershare template share" is set to the
name of an existing share, then all usershares created have their
defaults set from the parameters set on this share.

The target share may be set to be invalid for real file sharing by
setting the parameter "-valid = False" on the template share
definition. This causes it not to be seen as a real exported share
but to be able to be used as a template for usershares.

Default: usershare template share =

Example: usershare template share = template_share

use sendfile (S)

If this parameter is yes, and the sendfile() system call is
supported by the underlying operating system, then some SMB read
calls (mainly ReadAndX and ReadRaw) will use the more efficient
sendfile system call for files that are exclusively oplocked. This
may make more efficient use of the system CPU's and cause Samba to
be faster. Samba automatically turns this off for clients that use
protocol levels lower than NT LM 0.12 and when it detects a client
is Windows 9x (using sendfile from Linux will cause these clients
to fail).

Default: use sendfile = no

utmp (G)

This boolean parameter is only available if Samba has been
configured and compiled with the option --with-utmp. If set to yes
then Samba will attempt to add utmp or utmpx records (depending on
the UNIX system) whenever a connection is made to a Samba server.
Sites may use this to record the user connecting to a Samba share.

Due to the requirements of the utmp record, we are required to
create a unique identifier for the incoming user. Enabling this
option creates an n^2 algorithm to find this number. This may
impede performance on large installations.

Default: utmp = no

utmp directory (G)

This parameter is only available if Samba has been configured and
compiled with the option --with-utmp. It specifies a directory
pathname that is used to store the utmp or utmpx files (depending
on the UNIX system) that record user connections to a Samba server.
By default this is not set, meaning the system will use whatever
utmp file the native system is set to use (usually /var/run/utmp on
Linux).

Default: utmp directory = # Determined automatically

Example: utmp directory = /var/run/utmp

-valid (S)

This parameter indicates whether a share is valid and thus can be
used. When this parameter is set to false, the share will be in no
way visible nor accessible.

This option should not be used by regular users but might be of
help to developers. Samba uses this option internally to mark
shares as deleted.

Default: -valid = yes

valid users (S)

This is a list of users that should be allowed to login to this
service. Names starting with '@', '+' and '&' are interpreted using
the same rules as described in the invalid users parameter.

If this is empty (the default) then any user can login. If a
username is in both this list and the invalid users list then
access is denied for that user.

The current servicename is substituted for %S. This is useful in
the [homes] section.

Note: When used in the [global] section this parameter may have
unwanted side effects. For example: If samba is configured as a
MASTER BROWSER (see local master, os level, domain master,
preferred master) this option will prevent workstations from being
able to browse the network.

Default: valid users = # No valid users list (anyone can login)

Example: valid users = greg, @pcusers

veto files (S)

This is a list of files and directories that are neither visible
nor accessible. Each entry in the list must be separated by a '/',
which allows spaces to be included in the entry. '*' and '?' can be
used to specify multiple files or directories as in DOS wildcards.

Each entry must be a unix path, not a DOS path and must not include
the unix directory separator '/'.

Note that the case sensitive option is applicable in vetoing files.

One feature of the veto files parameter that it is important to be
aware of is Samba's behaviour when trying to delete a directory. If
a directory that is to be deleted contains nothing but veto files
this deletion will fail unless you also set the delete veto files
parameter to yes.

Setting this parameter will affect the performance of Samba, as it
will be forced to check all files and directories for a match as
they are scanned.

Examples of use include:

; Veto any files containing the word Security,
; any ending in .tmp, and any directory containing the
; word root.
veto files = /*Security*/*.tmp/*root*/

; Veto the Apple specific files that a NetAtalk server
; creates.
veto files = /.AppleDouble/.bin/.AppleDesktop/Network Trash Folder/

Default: veto files = # No files or directories are vetoed

veto oplock files (S)

This parameter is only valid when the oplocks parameter is turned
on for a share. It allows the Samba administrator to selectively
turn off the granting of oplocks on selected files that match a
wildcarded list, similar to the wildcarded list used in the veto
files parameter.

You might want to do this on files that you know will be heavily
contended for by clients. A good example of this is in the NetBench
SMB benchmark program, which causes heavy client contention for
files ending in .SEM. To cause Samba not to grant oplocks on these
files you would use the line (either in the [global] section or in
the section for the particular NetBench share.

An example of use is:

veto oplock files = /.*SEM/

Default: veto oplock files = # No files are vetoed for oplock
grants

vfs object

This parameter is a synonym for vfs objects.

vfs objects (S)

This parameter specifies the backend names which are used for Samba
VFS I/O operations. By default, normal disk I/O operations are used
but these can be overloaded with one or more VFS objects. Be aware
that the definition of this parameter will overwrite a possible
previous definition of the vfs objects parameter.

Default: vfs objects =

Example: vfs objects = extd_audit recycle

volume (S)

This allows you to override the volume label returned for a share.
Useful for CDROMs with installation programs that insist on a
particular volume label.

Default: volume = # the name of the share

volume serial number (S)

This allows to override the volume serial number (a 32bit value)
reported for a share.

The special value -1 (default) stands for a unique number that is
calculated for each share.

Default: volume serial number = -1

Example: volume serial number = 0xabcdefgh

wide links (S)

This parameter controls whether or not links in the UNIX file
system may be followed by the server. Links that point to areas
within the directory tree exported by the server are always
allowed; this parameter controls access only to areas that are
outside the directory tree being exported.

Note: Turning this parameter on when UNIX extensions are enabled
will allow UNIX clients to create symbolic links on the share that
can point to files or directories outside restricted path exported
by the share definition. This can cause access to areas outside of
the share. Due to this problem, this parameter will be
automatically disabled (with a message in the log file) if the unix
extensions option is on.

See the parameter allow insecure wide links if you wish to change
this coupling between the two parameters.

Default: wide links = no

winbind cache time (G)

This parameter specifies the number of seconds the winbindd(8)
daemon will cache user and group information before querying a
Windows NT server again.

This does not apply to authentication requests, these are always
evaluated in real time unless the winbind offline logon option has
been enabled.

Default: winbind cache time = 300

winbindd socket directory (G)

This setting controls the location of the winbind daemon's socket.

Except within automated test scripts, this should not be altered,
as the client tools (nss_winbind etc) do not honour this parameter.
Client tools must then be advised of the altered path with the
WINBINDD_SOCKET_DIR environment variable.

Default: winbindd socket directory = ${prefix}/var/run/winbindd

winbind enum groups (G)

On large installations using winbindd(8) it may be necessary to
suppress the enumeration of groups through the setgrent(),
getgrent() and endgrent() group of system calls. If the winbind
enum groups parameter is no, calls to the getgrent() system call
will not return any data.

Warning
Turning off group enumeration may cause some programs to behave
oddly.
Default: winbind enum groups = no

winbind enum users (G)

On large installations using winbindd(8) it may be necessary to
suppress the enumeration of users through the setpwent(),
getpwent() and endpwent() group of system calls. If the winbind
enum users parameter is no, calls to the getpwent system call will
not return any data.

Warning
Turning off user enumeration may cause some programs to behave
oddly. For example, the finger program relies on having access
to the full user list when searching for matching usernames.
Default: winbind enum users = no

winbind expand groups (G)

This option controls the maximum depth that winbindd will traverse
when flattening nested group memberships of Windows domain groups.
This is different from the winbind nested groups option which
implements the Windows NT4 model of local group nesting. The
"winbind expand groups" parameter specifically applies to the
membership of domain groups.

This option also affects the return of non nested group memberships
of Windows domain users. With the new default "winbind expand
groups = 0" winbind does not query group memberships at all.

Be aware that a high value for this parameter can result in system
slowdown as the main parent winbindd daemon must perform the group
unrolling and will be unable to answer incoming NSS or
authentication requests during this time.

The default value was changed from 1 to 0 with Samba 4.2. Some
broken applications (including some implementations of newgrp and
sg) calculate the group memberships of users by traversing groups,
such applications will require "winbind expand groups = 1". But the
new default makes winbindd more reliable as it doesn't require SAMR
access to domain controllers of trusted domains.

Default: winbind expand groups = 0

winbind:ignore domains (G)

Allows one to enter a list of trusted domains winbind should ignore
(untrust). This can avoid the overhead of resources from attempting
to login to DCs that should not be communicated with.

Default: winbind:ignore domains =

Example: winbind:ignore domains = DOMAIN1, DOMAIN2

winbind max clients (G)

This parameter specifies the maximum number of clients the
winbindd(8) daemon can connect with. The parameter is not a hard
limit. The winbindd(8) daemon configures itself to be able to
accept at least that many connections, and if the limit is reached,
an attempt is made to disconnect idle clients.

Default: winbind max clients = 200

winbind max domain connections (G)

This parameter specifies the maximum number of simultaneous
connections that the winbindd(8) daemon should open to the domain
controller of one domain. Setting this parameter to a value greater
than 1 can improve scalability with many simultaneous winbind
requests, some of which might be slow.

Note that if winbind offline logon is set to Yes, then only one DC
connection is allowed per domain, regardless of this setting.

Default: winbind max domain connections = 1

Example: winbind max domain connections = 10

winbind nested groups (G)

If set to yes, this parameter activates the support for nested
groups. Nested groups are also called local groups or aliases. They
work like their counterparts in Windows: Nested groups are defined
locally on any machine (they are shared between DC's through their
SAM) and can contain users and global groups from any trusted SAM.
To be able to use nested groups, you need to run nss_winbind.

Default: winbind nested groups = yes

winbind normalize names (G)

This parameter controls whether winbindd will replace whitespace in
user and group names with an underscore (_) character. For example,
whether the name "Space Kadet" should be replaced with the string
"space_kadet". Frequently Unix shell scripts will have difficulty
with usernames contains whitespace due to the default field
separator in the shell. If your domain possesses names containing
the underscore character, this option may cause problems unless the
name aliasing feature is supported by your nss_info plugin.

This feature also enables the name aliasing API which can be used
to make domain user and group names to a non-qualified version.
Please refer to the manpage for the configured idmap and nss_info
plugin for the specifics on how to configure name aliasing for a
specific configuration. Name aliasing takes precedence (and is
mutually exclusive) over the whitespace replacement mechanism
discussed previously.

Default: winbind normalize names = no

Example: winbind normalize names = yes

winbind nss info (G)

This parameter is designed to control how Winbind retrieves Name
Service Information to construct a user's home directory and login
shell. Currently the following settings are available:

o template - The default, using the parameters of template
shell and template homedir)

o _sfu | sfu20 | rfc2307 _ - When Samba is running in
security = ads and your Active Directory Domain
Controller does support the Microsoft "Services for
Unix" (SFU) LDAP schema, winbind can retrieve the login
shell and the home directory attributes directly from
your Directory Server. For SFU 3.0 or 3.5 simply choose
"sfu", if you use SFU 2.0 please choose "sfu20".

Note that for the idmap backend idmap_ad you need to
configure those settings in the idmap configuration
section. Make sure to consult the documentation of the
idmap backend that you are using.

Default: winbind nss info = template

Example: winbind nss info = sfu

winbind offline logon (G)

This parameter is designed to control whether Winbind should allow
one to login with the pam_winbind module using Cached Credentials.
If enabled, winbindd will store user credentials from successful
logins encrypted in a local cache.

Default: winbind offline logon = no

Example: winbind offline logon = yes

winbind reconnect delay (G)

This parameter specifies the number of seconds the winbindd(8)
daemon will wait between attempts to contact a Domain controller
for a domain that is determined to be down or not contactable.

Default: winbind reconnect delay = 30

winbind refresh tickets (G)

This parameter is designed to control whether Winbind should
refresh Kerberos Tickets retrieved using the pam_winbind module.

Default: winbind refresh tickets = no

Example: winbind refresh tickets = yes

winbind request timeout (G)

This parameter specifies the number of seconds the winbindd(8)
daemon will wait before disconnecting either a client connection
with no outstanding requests (idle) or a client connection with a
request that has remained outstanding (hung) for longer than this
number of seconds.

Default: winbind request timeout = 60

winbind rpc only (G)

Setting this parameter to yes forces winbindd to use RPC instead of
LDAP to retrieve information from Domain Controllers.

Default: winbind rpc only = no

winbind scan trusted domains (G)

This option only takes effect when the security option is set to
domain or ads. If it is set to yes, winbindd periodically tries to
scan for new trusted domains and adds them to a global list inside
of winbindd. The list can be extracted with wbinfo
--trusted-domains --verbose. Setting it to yes matches the
behaviour of Samba 4.7 and older.

The construction of that global list is not reliable and often
incomplete in complex trust setups. In most situations the list is
not needed any more for winbindd to operate correctly. E.g. for
plain file serving via SMB using a simple idmap setup with autorid,
tdb or ad. However some more complex setups require the list, e.g.
if you specify idmap backends for specific domains. Some
pam_winbind setups may also require the global list.

If you have a setup that doesn't require the global list, you
should set winbind scan trusted domains = no.

Default: winbind scan trusted domains = no

winbind sealed pipes (G)

This option controls whether any requests from winbindd to domain
controllers pipe will be sealed. Disabling sealing can be useful
for debugging purposes.

The behavior can be controlled per netbios domain by using 'winbind
sealed pipes:NETBIOSDOMAIN = no' as option.

Default: winbind sealed pipes = yes

winbind separator (G)

This parameter allows an admin to define the character used when
listing a username of the form of DOMAIN \user. This parameter is
only applicable when using the pam_winbind.so and nss_winbind.so
modules for UNIX services.

Please note that setting this parameter to + causes problems with
group membership at least on glibc systems, as the character + is
used as a special character for NIS in /etc/group.

Default: winbind separator = \

Example: winbind separator = +

winbind use default domain (G)

This parameter specifies whether the winbindd(8) daemon should
operate on users without domain component in their username. Users
without a domain component are treated as is part of the winbindd
server's own domain. While this does not benefit Windows users, it
makes SSH, FTP and e-mail function in a way much closer to the way
they would in a native unix system.

This option should be avoided if possible. It can cause confusion
about responsibilities for a user or group. In many situations it
is not clear whether winbind or /etc/passwd should be seen as
authoritative for a user, likewise for groups.

Default: winbind use default domain = no

Example: winbind use default domain = yes

winbind use krb5 enterprise principals (G)

winbindd is able to get kerberos tickets for pam_winbind with
krb5_auth or wbinfo -K/--krb5auth=.

winbindd (at least on a domain member) is never be able to have a
complete picture of the trust topology (which is managed by the
DCs). There might be uPNSuffixes and msDS-SPNSuffixes values, which
don't belong to any AD domain at all.

With winbind scan trusted domains = no winbindd doesn't even get a
complete picture of the topology.

It is not really required to know about the trust topology. We can
just rely on the [K]DCs of our primary domain (e.g.
PRIMARY.A.EXAMPLE.COM) and use enterprise principals e.g.
upnfromB@B.EXAMPLE.COM@PRIMARY.A.EXAMPLE.COM and follow the
WRONG_REALM referrals in order to find the correct DC. The final
principal might be userfromB@INTERNALB.EXAMPLE.PRIVATE.

With winbind use krb5 enterprise principals = yes winbindd
enterprise principals will be used.

Default: winbind use krb5 enterprise principals = yes

Example: winbind use krb5 enterprise principals = no

winsdb:local_owner (G)

This specifies the address that is stored in the winsOwner
attribute, of locally registered winsRecord-objects. The default is
to use the ip-address of the first network interface.

No default

winsdb:dbnosync (G)

This parameter disables fsync() after changes of the WINS database.

Default: winsdb:dbnosync = no

wins hook (G)

When Samba is running as a WINS server this allows you to call an
external program for all changes to the WINS database. The primary
use for this option is to allow the dynamic update of external name
resolution databases such as dynamic DNS.

The wins hook parameter specifies the name of a script or
executable that will be called as follows:

wins_hook operation name nametype ttl IP_list

o The first argument is the operation and is one of "add",
"delete", or "refresh". In most cases the operation can
be ignored as the rest of the parameters provide
sufficient information. Note that "refresh" may
sometimes be called when the name has not previously
been added, in that case it should be treated as an add.

o The second argument is the NetBIOS name. If the name is
not a legal name then the wins hook is not called. Legal
names contain only letters, digits, hyphens, underscores
and periods.

o The third argument is the NetBIOS name type as a 2 digit
hexadecimal number.

o The fourth argument is the TTL (time to live) for the
name in seconds.

o The fifth and subsequent arguments are the IP addresses
currently registered for that name. If this list is
empty then the name should be deleted.

An example script that calls the BIND dynamic DNS update program
nsupdate is provided in the examples directory of the Samba source
code.

No default

wins proxy (G)

This is a boolean that controls if nmbd(8) will respond to
broadcast name queries on behalf of other hosts. You may need to
set this to yes for some older clients.

Default: wins proxy = no

wins server (G)

This specifies the IP address (or DNS name: IP address for
preference) of the WINS server that nmbd(8) should register with.
If you have a WINS server on your network then you should set this
to the WINS server's IP.

You should point this at your WINS server if you have a
multi-subnetted network.

If you want to work in multiple namespaces, you can give every wins
server a 'tag'. For each tag, only one (working) server will be
queried for a name. The tag should be separated from the ip address
by a colon.

Note
You need to set up Samba to point to a WINS server if you have
multiple subnets and wish cross-subnet browsing to work
correctly.
See the chapter in the Samba3-HOWTO on Network Browsing.

Default: wins server =

Example: wins server = mary:192.9.200.1 fred:192.168.3.199
mary:192.168.2.61 # For this example when querying a certain name,
192.19.200.1 will be asked first and if that doesn't respond
192.168.2.61. If either of those doesn't know the name
192.168.3.199 will be queried.

Example: wins server = 192.9.200.1 192.168.2.61

wins support (G)

This boolean controls if the nmbd(8) process in Samba will act as a
WINS server. You should not set this to yes unless you have a
multi-subnetted network and you wish a particular nmbd to be your
WINS server. Note that you should NEVER set this to yes on more
than one machine in your network.

Default: wins support = no

workgroup (G)

This controls what workgroup your server will appear to be in when
queried by clients. Note that this parameter also controls the
Domain name used with the security = domain setting.

Default: workgroup = WORKGROUP

Example: workgroup = MYGROUP

wreplsrv:periodic_interval (G)

This maximum interval in seconds between 2 periodically scheduled
runs where we check for wins.ldb changes and do push notifications
to our push partners. Also wins_config.ldb changes are checked in
that interval and partner configuration reloads are done.

Default: wreplsrv:periodic_interval = 15

wreplsrv:propagate name releases (G)

If this parameter is enabled, then explicit (from the client) and
implicit (via the scavenging) name releases are propagated to the
other servers directly, even if there are still other addresses
active, this applies to SPECIAL GROUP (2) and MULTIHOMED (3)
entries. Also the replication conflict merge algorithm for SPECIAL
GROUP (2) entries discards replica addresses where the address
owner is the local server, if the address was not stored locally
before. The merge result is propagated directly in case an address
was discarded. A Windows servers doesn't propagate name releases of
SPECIAL GROUP (2) and MULTIHOMED (3) entries directly, which means
that Windows servers may return different results to name queries
for SPECIAL GROUP (2) and MULTIHOMED (3) names. The option doesn't
have much negative impact if Windows servers are around, but be
aware that they might return unexpected results.

Default: wreplsrv:propagate name releases = no

wreplsrv:scavenging_interval (G)

This is the interval in s between 2 scavenging runs which clean up
the WINS database and changes the states of expired name records.
Defaults to half of the value of wreplsrv:renew_interval.

No default

wreplsrv:tombstone_extra_timeout (G)

This is the time in s the server needs to be up till we'll remove
tombstone records from our database. Defaults to 3 days.

Default: wreplsrv:tombstone_extra_timeout = 259200

wreplsrv:tombstone_interval (G)

This is the interval in s till released records of the WINS server
become tombstone. Defaults to 6 days.

Default: wreplsrv:tombstone_interval = 518400

wreplsrv:tombstone_timeout (G)

This is the interval in s till tombstone records are deleted from
the WINS database. Defaults to 1 day.

Default: wreplsrv:tombstone_timeout = 86400

wreplsrv:verify_interval (G)

This is the interval in s till we verify active replica records
with the owning WINS server. Unfortunately not implemented yet.
Defaults to 24 days.

Default: wreplsrv:verify_interval = 2073600

writable

This parameter is a synonym for writeable.

write ok

This parameter is a synonym for writeable.

writeable (S)

Inverted synonym for read only.

Default: writeable = no

write list (S)

This is a list of users that are given read-write access to a
service. If the connecting user is in this list then they will be
given write access, no matter what the read only option is set to.
The list can include group names using the @group syntax.

Note that if a user is in both the read list and the write list
then they will be given write access.

Default: write list =

Example: write list = admin, root, @staff

write raw (G)

This is ignored if async smb echo handler is set, because this
feature is incompatible with raw write SMB requests

If enabled, raw writes allow writes of 65535 bytes in one packet.
This typically provides a major performance benefit for some very,
very old clients.

However, some clients either negotiate the allowable block size
incorrectly or are incapable of supporting larger block sizes, and
for these clients you may need to disable raw writes.

In general this parameter should be viewed as a system tuning tool
and left severely alone.

Default: write raw = yes

wtmp directory (G)

This parameter is only available if Samba has been configured and
compiled with the option --with-utmp. It specifies a directory
pathname that is used to store the wtmp or wtmpx files (depending
on the UNIX system) that record user connections to a Samba server.
The difference with the utmp directory is the fact that user info
is kept after a user has logged out.

By default this is not set, meaning the system will use whatever
utmp file the native system is set to use (usually /var/run/wtmp on
Linux).

Default: wtmp directory =

Example: wtmp directory = /var/log/wtmp

WARNINGS
Although the configuration file permits service names to contain
spaces, your client software may not. Spaces will be ignored in
comparisons anyway, so it shouldn't be a problem - but be aware of the
possibility.

On a similar note, many clients - especially DOS clients - limit
service names to eight characters. smbd(8) has no such limitation, but
attempts to connect from such clients will fail if they truncate the
service names. For this reason you should probably keep your service
names down to eight characters in length.

Use of the [homes] and [printers] special sections make life for an
administrator easy, but the various combinations of default attributes
can be tricky. Take extreme care when designing these sections. In
particular, ensure that the permissions on spool directories are
correct.

VERSION
This man page is part of version 4.19.5 of the Samba suite.

SEE ALSO
samba(7), smbpasswd(8), smbd(8), nmbd(8), winbindd(8), samba(8), samba-
tool(8), smbclient(1), nmblookup(1), testparm(1).

AUTHOR
The original Samba software and related utilities were created by
Andrew Tridgell. Samba is now developed by the Samba Team as an Open
Source project similar to the way the Linux kernel is developed.

Samba 4.19.5 02/19/2024 SMB.CONF(5)

Want to link to this manual page? Use this URL:
<https://man.freebsd.org/cgi/man.cgi?query=smb4.conf&sektion=5&manpath=FreeBSD+14.0-RELEASE+and+Ports>

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