10. Sharing

Shares are created to make part or all of a volume accessible to other computers on the network. The type of share to create depends on factors like which operating systems are being used by computers on the network, security requirements, and expectations for network transfer speeds.

FreeNAS® provides a Wizard for creating shares. The Wizard automatically creates the correct type of dataset and permissions for the type of share, sets the default permissions for the share type, and starts the service needed by the share. It is recommended to use the Wizard to create shares, fine-tune the share settings using the instructions in the rest of this chapter if needed, then fine-tune the default permissions from the client operating system to meet the requirements of the network.

Note

Shares are created to provide and control access to an area of storage. Before creating shares, it is recommended to make a list of the users that need access to storage data, which operating systems these users are using, whether all users should have the same permissions to the stored data, and whether these users should authenticate before accessing the data. This information can help determine which type of shares are needed, whether multiple datasets are needed to divide the storage into areas with different access and permissions, and how complex it will be to set up those permission requirements. Note that shares are used to provide access to data. When a share is deleted, it removes access to data but does not delete the data itself.

These types of shares and services are available:

  • AFP: Apple File Protocol shares are often used when the client computers all run Mac OS X. Apple has slowly shifted to preferring SMB for modern networks, although Time Machine still requires AFP.
  • Unix (NFS): Network File System shares are accessible from Mac OS X, Linux, BSD, and the professional and enterprise versions (but not the home editions) of Windows. This can be are a good choice when the client computers do not all run the same operating system but NFS client software is available for all of them.
  • WebDAV: WebDAV shares are accessible using an authenticated web browser (read-only) or WebDAV client running on any operating system.
  • SMB: Server Message Block shares, also known as Common Internet File System (CIFS) shares, are accessible by Windows, Mac OS X, Linux, and BSD computers. Access is slower than an NFS share due to the single-threaded design of Samba. SMB provides more configuration options than NFS and is a good choice on a network for Windows systems. However, it is a poor choice if the CPU on the FreeNAS® system is limited; if the CPU is maxed out, upgrade the CPU or consider another type of share.
  • Block (iSCSI): block or iSCSI shares appear as an unformatted disk to clients running iSCSI initiator software or a virtualization solution such as VMware. These are usually used as virtual drives.

Fast access from any operating system can be obtained by configuring the FTP service instead of a share and using a cross-platform FTP file manager application such as Filezilla. Secure FTP can be configured if the data needs to be encrypted.

When data security is a concern and the network users are familiar with SSH command line utilities or WinSCP, consider using the SSH service instead of a share. It is slower than unencrypted FTP due to the encryption overhead, but the data passing through the network is encrypted.

Note

It is generally a mistake to share a volume or dataset with more than one share type or access method. Different types of shares and services use different file locking methods. For example, if the same volume is configured to use both NFS and FTP, NFS will lock a file for editing by an NFS user, but a FTP user can simultaneously edit or delete that file. This results in lost edits and confused users. Another example: if a volume is configured for both AFP and SMB, Windows users can be confused by the “extra” filenames used by Mac files and delete them. This corrupts the files on the AFP share. Pick the one type of share or service that makes the most sense for the types of clients accessing that volume, and use that single type of share or service. To support multiple types of shares, divide the volume into datasets and use one dataset per share.

This section demonstrates configuration and fine-tuning of AFP, NFS, SMB, WebDAV, and iSCSI shares. FTP and SSH configurations are described in Services.

10.1. Apple (AFP) Shares

FreeNAS® uses the Netatalk AFP server to share data with Apple systems. This section describes the configuration screen for fine-tuning AFP shares created using the Wizard. It then provides configuration examples for using the Wizard to create a guest share, configuring Time Machine to back up to a dataset on the FreeNAS® system, and for connecting to the share from a Mac OS X client.

To view the AFP share created by the Wizard, click Sharing Apple (AFP) and highlight the name of the share. Click its Edit button to see the configuration options shown in Figure 10.1.1. The values showing for these options will vary, depending upon the information given when the share was created.

_images/afp2a.png

Fig. 10.1.1 Creating an AFP Share

Note

Table 10.1.1 summarizes the options available to fine-tune an AFP share. These options should usually be left at the default settings. Changing them might cause unexpected behavior. Most settings are only available with Advanced Mode. Do not change an advanced option without fully understanding the function of that option. Refer to Setting up Netatalk for a more detailed explanation of these options.

Table 10.1.1 AFP Share Configuration Options
Setting Value Description
Path browse button browse to the volume/dataset to share; do not nest additional volumes, datasets, or symbolic links beneath this path because Netatalk does not fully support that
Name string volume name which appears in the Mac computer’s connect to server dialog; limited to 27 characters and cannot contain a period
Share Comment string optional comment, only available in Advanced Mode
Allow List string only available in Advanced Mode; comma-delimited list of allowed users and/or groups where groupname begins with a @; note that adding an entry will deny any user/group that is not specified
Deny List string only available in Advanced Mode; comma-delimited list of denied users and/or groups where groupname begins with a @; note that adding an entry will allow all users/groups that are not specified
Read-only Access string only available in Advanced Mode; comma-delimited list of users and/or groups who only have read access where groupname begins with a @
Read-write Access string only available in Advanced Mode; comma-delimited list of users and/or groups who have read and write access where groupname begins with a @
Time Machine checkbox when checked, FreeNAS® advertises itself as a Time Machine disk so it can be found by Macs; due to a limitation in how the Mac deals with low-diskspace issues when multiple Macs share the same volume, checking Time Machine on multiple shares could result in intermittent failed backups
Zero Device Numbers checkbox only available in Advanced Mode; enable when the device number is not constant across a reboot
No Stat checkbox only available in Advanced Mode; if checked, AFP does not stat the volume path when enumerating the volumes list; useful for automounting or volumes created by a preexec script
AFP3 UNIX Privs checkbox only available in Advanced Mode; enable Unix privileges supported by OSX 10.5 and higher; do not enable this if the network contains Mac OS X 10.4 clients or lower as they do not support this feature
Default file permission checkboxes only available in Advanced Mode; only works with Unix ACLs; new files created on the share are set with the selected permissions
Default directory permission checkboxes only available in Advanced Mode; only works with Unix ACLs; new directories created on the share are set with the selected permissions
Default umask integer only available in Advanced Mode; umask used for newly created files, default is 000 (anyone can read, write, and execute)
Hosts Allow string only available in Advanced Mode; comma-, space-, or tab-delimited list of allowed hostnames or IP addresses
Hosts Deny string only available in Advanced Mode; comma-, space-, or tab-delimited list of denied hostnames or IP addresses
Auxiliary Parameters string additional afp.conf parameters not covered by other option fields

10.1.1. Creating AFP Guest Shares

AFP supports guest logins, meaning that Mac OS X users can access the AFP share without requiring their user accounts to first be created on or imported into the FreeNAS® system.

Note

When a guest share is created along with a share that requires authentication, AFP only maps users who log in as guest to the guest share. If a user logs in to the share that requires authentication, permissions on the guest share can prevent that user from writing to the guest share. The only way to allow both guest and authenticated users to write to a guest share is to set the permissions on the guest share to 777 or to add the authenticated users to a guest group and set the permissions to 77x.

Before creating a guest share, go to Services AFP and make sure that the Guest Access box is checked.

To create the AFP guest share, click Wizard, then click the Next button twice to display the screen shown in Figure 10.1.2. Complete these fields in this screen:

  1. Share name: enter a name for the share that is identifiable but less than 27 characters long. This name cannot contain a period. In this example, the share is named afp_guest.
  2. Click the button for Mac OS X (AFP).
  3. Click the Ownership button. Click the drop-down User menu and select nobody. Click the Return button to return to the previous screen.
  4. Click the Add button. The share is not created until the button is clicked. Clicking the Add button adds an entry to the Name frame with the name that was entered in Share name.
_images/afp6a.png

Fig. 10.1.2 Creating a Guest AFP Share

Click the Next button twice, then the Confirm button to create the share. The Wizard automatically creates a dataset for the share that contains the correct default permissions and starts the AFP service so the share is immediately available. The new share is also added as an entry to Sharing Apple (AFP).

Mac OS X users can connect to the guest AFP share by clicking Go Connect to Server. In the example shown in Figure 10.1.3, the user has entered afp:// followed by the IP address of the FreeNAS® system.

Click the Connect button. Once connected, Finder opens automatically. The name of the AFP share is displayed in the SHARED section in the left frame and the contents of any data saved in the share is displayed in the right frame.

_images/afp3.png

Fig. 10.1.3 Connect to Server Dialogue

To disconnect from the volume, click the eject button in the Shared sidebar.

10.1.2. Creating Authenticated and Time Machine Shares

Mac OS X includes the Time Machine application which can be used to schedule automatic backups. In this configuration example, a Time Machine user will be configured to backup to an AFP share on a FreeNAS® system. It is recommended to create a separate Time Machine share for each user that will be using Time Machine to backup their Mac OS X system to FreeNAS®. The process for creating an authenticated share for a user is the same as creating a Time Machine share for that user.

To use the Wizard to create an authenticated or Time Machine share, enter the following information, as seen in the example in Figure 10.1.4.

  1. Share name: enter a name for the share that is identifiable but less than 27 characters long. The name cannot contain a period. In this example, the share is named backup_user1.
  2. Click the button for Mac OS X (AFP) and check the box for Time Machine. If the user will not be using Time Machine, leave the box unchecked.
  3. Click the Ownership button. If the user already exists on the FreeNAS® system, click the drop-down User menu to select their user account. If the user does not yet exist on the FreeNAS® system, type their name into the User field and check the Create User checkbox. If the user will be a member of a group that already exists on the FreeNAS® system, click the drop-down Group menu to select the group name. To create a new group to be used by Time Machine users, enter the name in the Group field and check the Create Group checkbox. Otherwise, enter the same name as the user. In the example shown in Figure 10.1.5, both a new user1 user and a new tm_backups group will be created. Since a new user is being created, this screen prompts for the user password to be used when accessing the share. It also provides an opportunity to change the default permissions on the share. When finished, click Return to return to the screen shown in Figure 10.1.4.
  4. Click the Add button. Remember to do this or the share will not be created. Clicking the Add button adds an entry to the Name frame with the name that was entered in Share name.

To configure multiple authenticated or Time Machine shares, repeat for each user, giving each user their own Share name and Ownership. When finished, click the Next button twice, then the Confirm button to create the shares. The Wizard automatically creates a dataset for each share with the correct ownership and starts the AFP service so the shares are immediately available. The new shares are also added to Sharing Apple (AFP).

_images/afp7a.png

Fig. 10.1.4 Creating a Time Machine Share

_images/afp8.png

Fig. 10.1.5 Creating an Authenticated User

At this point, it may be desirable to configure a quota for each Time Machine share, to restrict backups from using all of the available space on the FreeNAS® system. The first time Time Machine makes a backup, it will create a full backup after waiting two minutes. It will then create a one hour incremental backup for the next 24 hours, and then one backup each day, each week and each month. Since the oldest backups are deleted when a Time Machine share becomes full, make sure that the quota size is sufficient to hold the desired number of backups. Note that a default installation of Mac OS X is ~21 GB in size.

To configure a quota, go to Storage Volumes and highlight the entry for the share. In the example shown in Figure 10.1.6, the Time Machine share name is backup_user1. Click the Edit Options button for the share, then Advanced Mode. Enter a value in the Quota for this dataset field, then click Edit Dataset to save the change. In this example, the Time Machine share is restricted to 200 GB.

_images/afp9a.png

Fig. 10.1.6 Setting a Quota

Note

An alternative is to create a global quota using the instructions in Set up Time Machine for multiple machines with OSX Server-Style Quotas.

To configure Time Machine on the Mac OS X client, go to System Preferences Time Machine which opens the screen shown in Figure 10.1.7. Click ON and a pop-up menu shows the FreeNAS® system as a backup option. In our example, it is listed as backup_user1 on “freenas”. Highlight the FreeNAS® system and click Use Backup Disk. A connection bar opens and prompts for the user account’s password–in this example, the password that was set for the user1 account.

_images/afp5.png

Fig. 10.1.7 Configuring Time Machine on Mac OS X Lion

If Time Machine could not complete the backup. The backup disk image could not be created (error 45) is shown when backing up to the FreeNAS® system, a sparsebundle image must be created using these instructions.

If Time Machine completed a verification of your backups. To improve reliability, Time Machine must create a new backup for you. is shown, follow the instructions in this post to avoid making another backup or losing past backups.

10.2. Unix (NFS) Shares

FreeNAS® supports sharing over the Network File System (NFS). Clients use the mount command to mount the share. Once mounted, the NFS share appears as just another directory on the client system. Some Linux distros require the installation of additional software in order to mount an NFS share. On Windows systems, enable Services for NFS in the Ultimate or Enterprise editions or install an NFS client application.

Note

For performance reasons, iSCSI is preferred to NFS shares when FreeNAS® is installed on ESXi. When considering creating NFS shares on ESXi, read through the performance analysis at Running ZFS over NFS as a VMware Store.

To create an NFS share using the Wizard, click the Next button twice to display the screen shown in Figure 10.2.1. Enter a Share name. Spaces are not allowed in these names. Click the button for Generic Unix (NFS), then click Add so the share name appears in the Name frame. When finished, click the Next button twice, then the Confirm button to create the share. Creating an NFS share using the wizard automatically creates a new dataset for the share, starts the services required for NFS, and adds an entry in Sharing Unix (NFS) Shares. Depending on your requirements, the IP addresses that are allowed to access the NFS share can be restricted, or the permissions adjusted.

_images/nfs6a.png

Fig. 10.2.1 NFS Share Wizard

NFS shares are edited by clicking Sharing Unix (NFS), highlighting the entry for the share, and clicking its Edit button. In the example shown in Figure 10.2.2, the configuration screen is open for the nfs_share1 share.

_images/nfs2.png

Fig. 10.2.2 NFS Share Settings

Table 10.2.1 summarizes the available configuration options in this screen. Some settings are only available by clicking the Advanced Mode button.

Table 10.2.1 NFS Share Options
Setting Value Advanced Mode Description
Path browse button   browse to the volume or dataset to be shared; click Add extra path to select multiple paths
Comment string   set the share name; if left empty, share name is the list of selected Path entries
Authorized networks string list of allowed networks in network/mask CIDR notation, like 1.2.3.0/24, space-delimited; leave empty to allow all
Authorized IP addresses or hosts string list of allowed IP addresses or hostnames, space-delimited; leave empty to allow all
All directories checkbox   when checked, allow the client to mount any subdirectory within the Path
Read only checkbox   prohibit writing to the share
Quiet checkbox inhibit otherwise-useful syslog diagnostics to avoid some annoying error messages; see exports(5) for examples
Maproot User drop-down menu when a user is selected, the root user is limited to that user’s permissions
Maproot Group drop-down menu when a group is selected, the root user is also limited to that group’s permissions
Mapall User drop-down menu the specified user’s permissions are used by all clients
Mapall Group drop-down menu the specified group’s permissions are used by all clients
Security selection only appears if Enable NFSv4 is checked in Services NFS; choices are sys or these Kerberos options: krb5 (authentication only), krb5i (authentication and integrity), or krb5p (authentication and privacy); if multiple security mechanisms are added to the Selected column using the arrows, use the Up or Down buttons to list in order of preference

When creating NFS shares, keep the following points in mind:

  1. Clients will specify the Path when mounting the share.
  2. The Maproot and Mapall options are exclusive, meaning only one can be used–the GUI does not allow both. The Mapall options supersede the Maproot options. To restrict only the root user’s permissions, set the Maproot option. To restrict permissions of all users, set the Mapall options.
  3. Each volume or dataset is considered to be its own filesystem and NFS is not able to cross filesystem boundaries.
  4. The network or host must be unique per share and per filesystem or directory.
  5. The All directories option can only be used once per share per filesystem.

To better understand these restrictions, consider the following scenario where there are:

  • 2 networks named 10.0.0.0/8 and 20.0.0.0/8
  • a ZFS volume named volume1 with 2 datasets named dataset1 and dataset2
  • dataset1 has a directory named directory1

Because of restriction #3, an error is shown when trying to create one NFS share like this:

  • Authorized networks set to 10.0.0.0/8 20.0.0.0/8
  • Path set to /mnt/volume1/dataset1 and /mnt/volume1/dataset1/directory1

Instead, set a Path of /mnt/volume1/dataset1 and check the All directories box.

That directory could also be restricted to one of the networks by creating two shares instead:

First NFS share:

  • Authorized networks set to 10.0.0.0/8
  • Path set to /mnt/volume1/dataset1

Second NFS share:

  • Authorized networks set to 20.0.0.0/8
  • Path set to /mnt/volume1/dataset1/directory1

Note that this requires the creation of two shares. It cannot be done with only one share.

10.2.1. Example Configuration

By default, the Mapall options show as N/A. This means that when a user connects to the NFS share, they connect with the permissions associated with their user account. This is a security risk if a user is able to connect as root as they will have complete access to the share.

A better scenario is to do the following:

  1. Specify the built-in nobody account to be used for NFS access.
  2. In the Change Permissions screen of the volume/dataset that is being shared, change the owner and group to nobody and set the permissions according to your requirements.
  3. Select nobody in the Mapall User and Mapall Group drop-down menus for the share in Sharing Unix (NFS) Shares.

With this configuration, it does not matter which user account connects to the NFS share, as it will be mapped to the nobody user account and will only have the permissions that were specified on the volume/dataset. For example, even if the root user is able to connect, it will not gain root access to the share.

10.2.2. Connecting to the Share

The following examples share this configuration:

  1. The FreeNAS® system is at IP address 192.168.2.2.
  2. A dataset named /mnt/volume1/nfs_share1 is created and the permissions set to the nobody user account and the nobody group.
  3. An NFS share is created with these attributes:
    • Path: /mnt/volume1/nfs_share1
    • Authorized Networks: 192.168.2.0/24
    • All Directories checkbox is checked
    • MapAll User is set to nobody
    • MapAll Group is set to nobody

10.2.2.1. From BSD or Linux

The NFS share is mounted on BSD or Linux systems needing access with this command executed as the superuser or with sudo:

mount -t nfs 192.168.2.2:/mnt/volume1/nfs_share1 /mnt
  • -t nfs specifies the filesystem type of the share
  • 192.168.2.2 is the IP address of the FreeNAS® system
  • /mnt/volume/nfs_share1 is the name of the directory to be shared, a dataset in this case
  • /mnt is the mountpoint on the client system. This must be an existing, empty directory. The data in the NFS share appears in this directory on the client computer.

A successful mounting of the share returns to the command prompt without any status or error messages.

Note

If this command fails on a Linux system, make sure that the nfs-utils package is installed.

This configuration allows users on the client system to copy files to and from /mnt (the mount point). All files are owned by nobody:nobody. Changes to any files or directories in /mnt are written to the FreeNAS® system’s /mnt/volume1/nfs_share1 dataset.

Settings cannot be changed on the NFS share if it is mounted on any client computers. The umount command is used to unmount the share on BSD and Linux clients. Run it as the superuser or with sudo on each client computer:

umount /mnt

10.2.2.2. From Microsoft

Windows NFS client support varies with versions and releases. For best results, use Windows (SMB) Shares.

10.2.2.3. From Mac OS X

To mount the NFS volume from a Mac OS X client, click on Go Connect to Server. In the Server Address field, enter nfs:// followed by the IP address of the FreeNAS® system and the name of the volume/dataset being shared by NFS. The example shown in Figure 10.2.3 continues with our example of 192.168.2.2:/mnt/volume1/nfs_share1.

Finder opens automatically after connecting. The IP address of the FreeNAS® system is displayed in the SHARED section in the left frame and the contents of the share are displayed in the right frame. In the example shown in Figure 10.2.4, /mnt/data has one folder named images. The user can now copy files to and from the share.

_images/nfs3a.png

Fig. 10.2.3 Mounting the NFS Share from Mac OS X

_images/nfs4a.png

Fig. 10.2.4 Viewing the NFS Share in Finder

10.2.3. Troubleshooting NFS

Some NFS clients do not support the NLM (Network Lock Manager) protocol used by NFS. This is the case if the client receives an error that all or part of the file may be locked when a file transfer is attempted. To resolve this error, add the option -o nolock when running the mount command on the client to allow write access to the NFS share.

If a “time out giving up” error is shown when trying to mount the share from a Linux system, make sure that the portmapper service is running on the Linux client. If portmapper is running and timeouts are still shown, force the use of TCP by including -o tcp in the mount command.

If a “RPC: Program not registered” error is shown, upgrade to the latest version of FreeNAS® and restart the NFS service after the upgrade to clear the NFS cache.

If clients see “reverse DNS” errors, add the FreeNAS® IP address in the Host name database field of Network Global Configuration.

If clients receive timeout errors when trying to mount the share, add the client IP address and hostname to the Host name data base field in Network Global Configuration.

Some older versions of NFS clients default to UDP instead of TCP and do not auto-negotiate for TCP. By default, FreeNAS® uses TCP. To support UDP connections, go to Services NFS and check the box Serve UDP NFS clients.

10.3. WebDAV Shares

In FreeNAS®, WebDAV shares can be created so that authenticated users can browse the contents of the specified volume, dataset, or directory from a web browser.

Configuring WebDAV shares is a two step process. First, create the WebDAV shares to specify which data can be accessed. Then, configure the WebDAV service by specifying the port, authentication type, and authentication password. Once the configuration is complete, the share can be accessed using a URL in the format:

protocol://IP_address:port_number/share_name

where:

  • protocol: is either http or https, depending upon the Protocol configured in Services WebDAV.
  • IP address: is the IP address or hostname of the FreeNAS® system. Take care when configuring a public IP address to ensure that the network’s firewall only allows access to authorized systems.
  • port_number: is configured in Services WebDAV. If the FreeNAS® system is to be accessed using a public IP address, consider changing the default port number and ensure that the network’s firewall only allows access to authorized systems.
  • share_name: is configured in Sharing WebDAV Shares.

Entering the URL in a web browser brings up an authentication pop-up message. Enter a username of webdav and the password configured in Services WebDAV.

Warning

At this time, only the webdav user is supported. For this reason, it is important to set a good password for this account and to only give the password to users which should have access to the WebDAV share.

To create a WebDAV share, click Sharing WebDAV Shares Add WebDAV Share which will open the screen shown in Figure 10.3.1.

_images/webdav.png

Fig. 10.3.1 Adding a WebDAV Share

Table 10.3.1 summarizes the available options.

Table 10.3.1 WebDAV Share Options
Setting Value Description
Share Path Name string input a name for the share
Comment string optional
Path browse button browse to the volume/dataset to share
Read Only checkbox if checked, users cannot write to the share
Change User & Group Ownership checkbox if checked, automatically sets the share’s contents to the webdav user and group

After clicking OK, a pop-up asks about enabling the service. Once the service starts, review the settings in Services WebDAV as they are used to determine which URL is used to access the WebDAV share and whether or not authentication is required to access the share. These settings are described in WebDAV.

10.4. Windows (SMB) Shares

FreeNAS® uses Samba to share volumes using Microsoft’s SMB protocol. SMB is built into the Windows and Mac OS X operating systems and most Linux and BSD systems pre-install the Samba client in order to provide support for SMB. If your distro did not, install the Samba client using the distro’s software repository.

The SMB protocol supports many different types of configuration scenarios, ranging from the very simple to quite complex. The complexity of the scenario depends upon the types and versions of the client operating systems that will connect to the share, whether the network has a Windows server, and whether Active Directory is being used. Depending on the authentication requirements, it might be necessary to create or import users and groups.

Samba supports server-side copy of files on the same share with clients from Windows 8 and higher. Copying between two different shares is not server-side. Windows 7 clients support server-side copying with Robocopy.

This chapter starts by summarizing the available configuration options. It demonstrates some common configuration scenarios as well as offering some troubleshooting tips. It is recommended to first read through this entire chapter before creating any SMB shares to get a better idea of the configuration scenario that best meets your network’s needs.

Tip

SMB Tips and Tricks shows helpful hints for configuring and managing SMB networking. The FreeNAS and Samba (CIFS) permissions and Advanced Samba (CIFS) permissions on FreeNAS videos clarify setting up permissions on SMB shares.

Tip

Run smbstatus from the Shell for a list of active connections and users.

Figure 10.4.1 shows the configuration screen that appears after clicking Sharing Windows (SMB Shares) Add Windows (SMB) Share.

_images/cifs2a.png

Fig. 10.4.1 Adding an SMB Share

Table 10.4.1 summarizes the options when creating a SMB share. Some settings are only available after clicking the Advanced Mode button. For simple sharing scenarios, Advanced Mode options are not needed. For more complex sharing scenarios, only change an Advanced Mode option after fully understanding the function of that option. smb.conf(5) provides more details for each configurable option.

Table 10.4.1 Options for a SMB Share
Setting Value Description
Path browse button select volume/dataset/directory to share
Use as home share checkbox check this box if the share is meant to hold user home directories; only one share can be the homes share
Name string mandatory; name of share
Comment string only available in Advanced Mode; optional description
Apply Default Permissions checkbox sets the ACLs to allow read/write for owner/group and read-only for others; should only be unchecked when creating a share on a system that already has custom ACLs set
Export Read Only checkbox only available in Advanced Mode; prohibits write access to the share
Browsable to Network Clients checkbox only available in Advanced Mode; when checked, users see the contents of /homes (including other home directories of other users) and when unchecked, users see only their own home directory
Export Recycle Bin checkbox only available in Advanced Mode; deleted files are moved to a hidden .recycle in the root folder of the share; the .recycle directory can be deleted to reclaim space and is automatically recreated when a file is deleted
Show Hidden Files checkbox only available in Advanced Mode; if enabled, the Windows hidden attribute is not set when filenames that begin with a dot (a Unix hidden file) are created; existing files are not affected
Allow Guest Access checkbox if checked, no password is required to connect to the share and all users share the permissions of the guest user defined in the SMB service
Only Allow Guest Access checkbox only available in Advanced Mode; requires Allow guest access to also be checked; forces guest access for all connections
Hosts Allow string only available in Advanced Mode; comma-, space-, or tab-delimited list of allowed hostnames or IP addresses
Hosts Deny string only available in Advanced Mode; comma-, space-, or tab-delimited list of denied hostnames or IP addresses; allowed hosts take precedence so can use ALL in this field and specify allowed hosts in Hosts Allow
VFS Objects selection only available in Advanced Mode; adds virtual file system modules to enhance functionality; Table 10.4.2 summarizes the available modules
Periodic Snapshot Task drop-down menu used to configure home directory shadow copies on a per-share basis; select the pre-configured periodic snapshot task to use for the share’s shadow copies
Auxiliary Parameters string only available in Advanced Mode; additional smb4.conf parameters not covered by other option fields

Note the following regarding some of the Advanced Mode settings:

  • Hostname lookups add some time to accessing the SMB share. If you only use IP addresses, uncheck the Hostnames lookups box in Services SMB.
  • Be careful about unchecking the Browsable to Network Clients box. When this box is checked (the default), other users will see the names of every share that exists using Windows Explorer, but they will receive a permissions denied error message if they try to access someone else’s share. If this box is unchecked, even the owner of the share will not see it or be able to create a drive mapping for the share in Windows Explorer. However, they can still access the share from the command line. Unchecking this option provides limited security and is not a substitute for proper permissions and password control.
  • If some files on a shared volume should be hidden and inaccessible to users, put a veto files= line in the Auxiliary Parameters field. The syntax for the veto files option and some examples can be found in the smb.conf manual page.

To configure support for OS/2 clients, add this line to Auxiliary Parameters:

lanman auth = yes

To configure lanman authentication for pre-NT authentication, add these lines instead:

client lanman auth = yes
client plaintext auth = yes

Table 10.4.2 provides an overview of the available VFS modules. Be sure to research each module before adding or deleting it from the Selected column of the VFS Objects field of the share. Some modules need additional configuration after they are added. Refer to Stackable VFS modules and the vfs_* man pages for more details.

Table 10.4.2 Available VFS Modules
Value Description
acl_tdb stores NTFS ACLs in a tdb file to enable full mapping of Windows ACLs
acl_xattr stores NTFS ACLs in Extended Attributes (EAs) to enable the full mapping of Windows ACLs
aio_fork enables async I/O
aio_posix enables asynchronous I/O on systems running POSIX kernels
aio_pthread implements async I/O in Samba vfs using a pthread pool instead of the internal Posix AIO interface
audit logs share access, connects/disconnects, directory opens/creates/removes, and file opens/closes/renames/unlinks/chmods to syslog
cacheprime primes the kernel file data cache
cap translates filenames to and from the CAP encoding format, commonly used in Japanese language environments
catia creates filenames that use characters that are illegal in SMB filenames
commit tracks the amount of data written to a file and synchronizes it to disk when a specified amount accumulates
crossrename allows server side rename operations even if source and target are on different physical devices
default_quota stores the default quotas that are reported to a windows client in the quota record of a user
dfs_samba4 distributed file system for providing an alternative name space, load balancing, and automatic failover
dirsort sorts directory entries alphabetically before sending them to the client
expand_msdfs enables support for Microsoft Distributed File System (DFS)
extd_audit sends audit logs to both syslog and the Samba log files
fake_acls stores file ownership and ACLs as extended attributes
fake_perms allows roaming profile files and directories to be set as read-only
fruit enhances OS X support by providing the SMB2 AAPL extension and Netatalk interoperability (see NOTE below table)
full_audit record selected client operations to the system log; if selected, a warning will indicate that Windows 10 clients may experience issues when transferring files to the NAS system when this module is enabled
linux_xfs_sgid used to work around an old Linux XFS bug
media_harmony allows Avid editorial workstations to share a network drive
netatalk eases the co-existence of SMB and AFP shares
posix_eadb provides Extended Attributes (EAs) support so they can be used on filesystems which do not provide native support for EAs
preopen useful for video streaming applications that want to read one file per frame
readahead useful for Windows Vista clients reading data using Windows Explorer
readonly marks a share as read-only for all clients connecting within the configured time period
scannedonly ensures that only files that have been scanned for viruses are visible and accessible
shadow_copy allows Microsoft shadow copy clients to browse shadow copies on Windows shares
shadow_copy_test shadow copy testing
shell_snap provides shell-script callouts for snapshot creation and deletion operations issued by remote clients using the File Server Remote VSS Protocol (FSRVP)
skel_opaque implements dummy versions of all VFS modules (useful to VFS module developers)
skel_transparent implements dummy passthrough functions of all VFS modules (useful to VFS module developers)
smb_traffic_analyzer logs Samba read and write operations through a socket to a helper application
snapper provides the ability for remote SMB clients to access shadow copies of FSRVP snapshots using Windows Explorer
streams_depot experimental module to store alternate data streams in a central directory
streams_xattr enables storing of NTFS alternate data streams in the file system
syncops ensures metadata operations are performed synchronously
time_audit logs system calls that take longer than the number of defined milliseconds
unityed_media allows multiple Avid clients to share a network drive
winmsa emulate Microsoft’s MoveSecurityAttributes=0 registry option, setting the ACL for file and directory hierarchies to inherit from the parent directory into which they are moved
worm controls the writability of files and folders depending on their change time and an adjustable grace period
xattr_tdb stores Extended Attributes (EAs) in a tdb file so they can be used on filesystems which do not provide support for EAs

Note

When using fruit, also add the streams_xattr and catia VFS objects and be sure to configure all SMB shares this way. Reboot the Mac client after making this change.

These VFS objects do not appear in the drop-down menu as they are always enabled:

  • recycle: moves deleted files to the recycle directory instead of deleting them
  • shadow_copy2: a more recent implementation of shadow_copy with some additional features
  • zfs_space: correctly calculates ZFS space used by share, including any reservations or quotas
  • zfsacl: provide ACL extensions for proper integration with ZFS.

10.4.1. Configuring Unauthenticated Access

SMB supports guest logins, meaning that users can access the SMB share without needing to provide a username or password. This type of share is convenient as it is easy to configure, easy to access, and does not require any users to be configured on the FreeNAS® system. This type of configuration is also the least secure as anyone on the network can access the contents of the share. Additionally, since all access is as the guest user, even if the user inputs a username or password, there is no way to differentiate which users accessed or modified the data on the share. This type of configuration is best suited for small networks where quick and easy access to the share is more important than the security of the data on the share.

To configure an unauthenticated SMB share, click Wizard, then click the Next button twice to display the screen shown in Figure 10.4.2. Complete the following fields in this screen:

  1. Share name: enter a name for the share that is useful to you. In this example, the share is named smb_insecure.
  2. Click the button for Windows (SMB) and check the box for Allow Guest.
  3. Click the Ownership button. Click the drop-down User menu and select nobody. Click the Return button to return to the previous screen.
  4. Click the Add button. If you forget to do this, the share will not be created. Clicking the Add button adds an entry to the Name frame with the name that was entered in Share name.
_images/cifs7a.png

Fig. 10.4.2 Creating an Unauthenticated SMB Share

Click the Next button twice, then the Confirm button to create the share. The Wizard automatically creates a dataset for the share and starts the SMB service so the share is immediately available. The new share is also be added to Sharing Windows (SMB).

Users can now access the share from any SMB client and will not be prompted for their username or password. For example, to access the share from a Windows system, open Explorer and click on Network. For this configuration example, a system named FREENAS appears with a share named insecure_smb. The user can copy data to and from the unauthenticated SMB share.

10.4.2. Configuring Authenticated Access Without a Domain Controller

Most configuration scenarios require each user to have their own user account and to authenticate before accessing the share. This allows the administrator to control access to data, provide appropriate permissions to that data, and to determine who accesses and modifies stored data. A Windows domain controller is not needed for authenticated SMB shares, which means that additional licensing costs are not required. However, since there is no domain controller to provide authentication for the network, each user account needs to be created on the FreeNAS® system. This type of configuration scenario is often used in home and small networks as it does not scale well if many users accounts are needed.

Before configuring this scenario, determine which users will need authenticated access. While not required for the configuration, it eases troubleshooting if the username and password that will be created on the FreeNAS® system matches that information on the client system. Next, determine if each user should have their own share to store their own data or if several users will be using the same share. The simpler configuration is to make one share per user as it does not require the creation of groups, adding the correct users to the groups, and ensuring that group permissions are set correctly.

To use the Wizard to create an authenticated SMB share, enter the following information, as shown in the example in Figure 10.4.3.

  1. Share name: enter a name for the share that is useful to you. In this example, the share is named smb_user1.
  2. Click the button for Windows (SMB).
  3. Click the Ownership button. To create the user account on the FreeNAS® system, type their name into the User field and check the Create User checkbox. The user’s password is then entered and confirmed. If the user will not be sharing this share with other users, type their name into the Group field and click Create Group. If, however, the share will be used by several users, instead type in a group name and check the Create Group box. In the example shown in Figure 10.4.4, user1 has been used for both the user and group name, meaning that this share will only be used by user1. When finished, click Return to return to the screen shown in Figure 10.4.3.
  4. Click the Add button. If you forget to do this, the share will not be created. Clicking the Add button adds an entry to the Name frame with the name that was entered in Share name.

If you wish to configure multiple authenticated shares, repeat for each user, giving each user their own Share name and Ownership. When finished, click Next twice, then Confirm to create the shares. The Wizard automatically creates a dataset with the correct ownership for each share and starts the SMB service so the shares are available immediately. The new shares are also added to Sharing Windows (SMB).

_images/cifs3a.png

Fig. 10.4.3 Creating an Authenticated SMB Share

_images/cifs8.png

Fig. 10.4.4 Creating the User and Group

The authenticated share can now be tested from any SMB client. For example, to test an authenticated share from a Windows system, open Explorer and click on Network. For this configuration example, a system named FREENAS appears with a share named smb_user1. If you click on smb_user1, a Windows Security pop-up screen prompts for that user’s username and password. Enter the values that were configured for that share, in this case user user1. After authentication, the user can copy data to and from the SMB share.

To prevent Windows Explorer from hanging when accessing the share, map the share as a network drive. To do this, right-click the share and select Map network drive.... Choose a drive letter from the drop-down menu and click the Finish button.

Note that Windows systems cache a user’s credentials. This can cause issues when testing or accessing multiple authenticated shares as only one authentication is allowed at a time. If you are having problems authenticating to a share and are sure that you are entering the correct username and password, type cmd in the Search programs and files box and use the following command to see if you have already authenticated to a share. In this example, the user has already authenticated to the smb_user1 share:

net use
New connections will be remembered.

Status         Local   Remote                  Network
------------------------------------------------------------------------
OK                     \\FREENAS\smb_user1 Microsoft Windows Network
The command completed successfully.

To clear the cache:

net use * /DELETE
You have these remote connections:
               \\FREENAS\smb_user1
Continuing will cancel the connections.

Do you want to continue this operation? <Y/N> [N]: y

An additional warning is shown if the share is currently open in Explorer:

There are open files and/or incomplete directory searches pending on the connection
to \\FREENAS|smb_user1.

Is it OK to continue disconnecting and force them closed? <Y/N> [N]: y
The command completed successfully.

The next time a share is accessed with Explorer, you will be prompted to authenticate.

10.4.3. Configuring Shadow Copies

Shadow Copies, also known as the Volume Shadow Copy Service (VSS) or Previous Versions, is a Microsoft service for creating volume snapshots. Shadow copies allow you to easily restore previous versions of files from within Windows Explorer. Shadow Copy support is built into Vista and Windows 7. Windows XP or 2000 users need to install the Shadow Copy client.

When you create a periodic snapshot task on a ZFS volume that is configured as a SMB share in FreeNAS®, it is automatically configured to support shadow copies.

Before using shadow copies with FreeNAS®, be aware of the following caveats:

  • If the Windows system is not fully patched to the latest service pack, Shadow Copies may not work. If you are unable to see any previous versions of files to restore, use Windows Update to make sure that the system is fully up-to-date.
  • Shadow copy support only works for ZFS pools or datasets. This means that the SMB share must be configured on a volume or dataset, not on a directory.
  • Datasets are filesystems and shadow copies cannot traverse filesystems. If you want to be able to see the shadow copies in your child datasets, create separate shares for them.
  • Shadow copies will not work with a manual snapshot, you must create a periodic snapshot task for the pool or dataset being shared by SMB or a recursive task for a parent dataset.
  • The periodic snapshot task should be created and at least one snapshot should exist before creating the SMB share. If the SMB share was created first, restart the SMB service in Services Control Services.
  • Appropriate permissions must be configured on the volume/dataset being shared by SMB.
  • Users cannot delete shadow copies on the Windows system due to the way Samba works. Instead, the administrator can remove snapshots from the FreeNAS® administrative GUI. The only way to disable shadow copies completely is to remove the periodic snapshot task and delete all snapshots associated with the SMB share.

To configure shadow copy support, use the instructions in Configuring Authenticated Access Without a Domain Controller to create the desired number of shares. In this configuration example, a Windows 7 computer has two users: user1 and user2. For this example, two authenticated shares are created so that each user account has their own share. The first share is named user1 and the second share is named user2. Then:

  1. Use Storage Periodic Snapshot Tasks Add Periodic Snapshot to create at least one periodic snapshot task. You can either create a snapshot task for each user’s dataset, in this example the datasets /mnt/volume1/user1 and /mnt/volume1/user2, or you can create one periodic snapshot task for the entire volume, in this case /mnt/volume1. Before continuing to the next step, confirm that at least one snapshot for each defined task is displayed in the Storage Snapshots tab. When creating the schedule for the periodic snapshot tasks, keep in mind how often your users need to access modified files and during which days and time of day they are likely to make changes.
  2. Go to Sharing Windows (SMB) Shares. Highlight a share and click Edit, then Advanced Mode. Click the Periodic Snapshot Task drop-down menu and select the periodic snapshot task to use for that share. Repeat for each share being configured as a shadow copy. For this example, the share named /mnt/volume1/user1 is configured to use a periodic snapshot task that was configured to take snapshots of the /mnt/volume1/user1 dataset and the share named /mnt/volume1/user2 is configured to use a periodic snapshot task that was configured to take snapshots of the /mnt/volume1/user2 dataset.
  3. Verify that the SMB service is set to ON in Services Control Services.

Figure 10.4.5 provides an example of using shadow copies while logged in as user1 on the Windows system. In this example, the user right-clicked modified file and selected Restore previous versions from the menu. This particular file has three versions: the current version, plus two previous versions stored on the FreeNAS® system. The user can choose to open one of the previous versions, copy a previous version to the current folder, or restore one of the previous versions, overwriting the existing file on the Windows system.

_images/cifs6.png

Fig. 10.4.5 Viewing Previous Versions within Explorer

10.5. Block (iSCSI)

iSCSI is a protocol standard for the consolidation of storage data. iSCSI allows FreeNAS® to act like a storage area network (SAN) over an existing Ethernet network. Specifically, it exports disk devices over an Ethernet network that iSCSI clients (called initiators) can attach to and mount. Traditional SANs operate over fibre channel networks which require a fibre channel infrastructure such as fibre channel HBAs, fibre channel switches, and discrete cabling. iSCSI can be used over an existing Ethernet network, although dedicated networks can be built for iSCSI traffic in an effort to boost performance. iSCSI also provides an advantage in an environment that uses Windows shell programs; these programs tend to filter “Network Location” but iSCSI mounts are not filtered.

Before configuring the iSCSI service, be familiar with this iSCSI terminology:

CHAP: an authentication method which uses a shared secret and three-way authentication to determine if a system is authorized to access the storage device and to periodically confirm that the session has not been hijacked by another system. In iSCSI, the initiator (client) performs the CHAP authentication.

Mutual CHAP: a superset of CHAP in that both ends of the communication authenticate to each other.

Initiator: a client which has authorized access to the storage data on the FreeNAS® system. The client requires initiator software to initiate the connection to the iSCSI share.

Target: a storage resource on the FreeNAS® system. Every target has a unique name known as an iSCSI Qualified Name (IQN).

Internet Storage Name Service (iSNS): protocol for the automated discovery of iSCSI devices on a TCP/IP network.

Extent: the storage unit to be shared. It can either be a file or a device.

Portal: indicates which IP addresses and ports to listen on for connection requests.

LUN: stands for Logical Unit Number and represents a logical SCSI device. An initiator negotiates with a target to establish connectivity to a LUN; the result is an iSCSI connection that emulates a connection to a SCSI hard disk. Initiators treat iSCSI LUNs the same way as they would a raw SCSI or IDE hard drive; rather than mounting remote directories, initiators format and directly manage filesystems on iSCSI LUNs. When configuring multiple iSCSI LUNs, create a new target for each LUN. Since iSCSI multiplexes a target with multiple LUNs over the same TCP connection, you will experience contention from TCP if there is more than one target per LUN.

In FreeNAS®, iSCSI is built into the kernel. This version of iSCSI supports Microsoft Offloaded Data Transfer (ODX), meaning that file copies happen locally, rather than over the network. It also supports the VAAI (vStorage APIs for Array Integration) primitives for efficient operation of storage tasks directly on the NAS. To take advantage of the VAAI primitives, create a zvol using the instructions in Create zvol and use it to create a device extent, as described in Extents.

To configure iSCSI:

  1. Review the target global configuration parameters.
  2. Create at least one portal.
  3. Determine which hosts are allowed to connect using iSCSI and create an initiator.
  4. Decide if authentication will be used, and if so, whether it will be CHAP or mutual CHAP. If using authentication, create an authorized access.
  5. Create a target.
  6. Create either a device or a file extent to be used as storage.
  7. Associate a target with an extent.
  8. Start the iSCSI service in Services Control Services.

The rest of this section describes these steps in more detail.

10.5.1. Target Global Configuration

Sharing Block (iSCSI) Target Global Configuration, shown in Figure 10.5.1, contains settings that apply to all iSCSI shares. Table 10.5.1 summarizes the settings that can be configured in the Target Global Configuration screen.

Some built-in values affect iSNS usage. Fetching of allowed initiators from iSNS is not implemented, so target ACLs must be configured manually. To make iSNS registration useful, iSCSI targets should have explicitly configured port IP addresses. This avoids initiators attempting to discover unconfigured target portal addresses like 0.0.0.0.

The iSNS registration period is 900 seconds. Registered Network Entities not updated during this period are unregistered. The timeout for iSNS requests is 5 seconds.

_images/global1c.png

Fig. 10.5.1 iSCSI Target Global Configuration Variables

Table 10.5.1 Target Global Configuration Settings
Setting Value Description
Base Name string see the “Constructing iSCSI names using the iqn. format” section of RFC 3721 if unfamiliar with this format
ISNS Servers string space delimited list of hostnames or IP addresses of ISNS servers with which to register the system’s iSCSI targets and portals
Pool Available Space Threshold integer enter the percentage of free space that should remain in the pool; when this percentage is reached, the system issues an alert, but only if zvols are used; see VAAI Threshold Warning

10.5.2. Portals

A portal specifies the IP address and port number to be used for iSCSI connections. Sharing Block (iSCSI) Portals Add Portal brings up the screen shown in Figure 10.5.2.

Table 10.5.2 summarizes the settings that can be configured when adding a portal. If you need to assign additional IP addresses to the portal, click the link Add extra Portal IP.

_images/portal1a.png

Fig. 10.5.2 Adding an iSCSI Portal

Table 10.5.2 Portal Configuration Settings
Setting Value Description
Comment string optional description; portals are automatically assigned a numeric group ID
Discovery Auth Method drop-down menu configures the authentication level required by the target for discovery of valid devices, where None will allow anonymous discovery while CHAP and Mutual CHAP require authentication
Discovery Auth Group drop-down menu select a user created in Authorized Access if the Discovery Auth Method is set to CHAP or Mutual CHAP
IP address drop-down menu select the IP address associated with an interface or the wildcard address of 0.0.0.0 (any interface)
Port integer TCP port used to access the iSCSI target; default is 3260

FreeNAS® systems with multiple IP addresses or interfaces can use a portal to provide services on different interfaces or subnets. This can be used to configure multi-path I/O (MPIO). MPIO is more efficient than a link aggregation.

If the FreeNAS® system has multiple configured interfaces, portals can also be used to provide network access control. For example, consider a system with four interfaces configured with the following addresses:

192.168.1.1/24

192.168.2.1/24

192.168.3.1/24

192.168.4.1/24

You could create a portal containing the first two IP addresses (group ID 1) and a portal containing the remaining two IP addresses (group ID 2). You could then create a target named A with a Portal Group ID of 1 and a second target named B with a Portal Group ID of 2. In this scenario, the iSCSI service would listen on all four interfaces, but connections to target A would be limited to the first two networks and connections to target B would be limited to the last two networks.

Another scenario would be to create a portal which includes every IP address except for the one used by a management interface. This would prevent iSCSI connections to the management interface.

10.5.3. Initiators

The next step is to configure authorized initiators, or the systems which are allowed to connect to the iSCSI targets on the FreeNAS® system. To configure which systems can connect, use Sharing Block (iSCSI) Initiators Add Initiator, shown in Figure 10.5.3.

_images/initiator1.png

Fig. 10.5.3 Adding an iSCSI Initiator

Table 10.5.3 summarizes the settings that can be configured when adding an initiator.

Table 10.5.3 Initiator Configuration Settings
Setting Value Description
Initiators string use ALL keyword or a list of initiator hostnames separated by spaces
Authorized network string use ALL keyword or a network address with CIDR mask such as 192.168.2.0/24
Comment string optional description

In the example shown in Figure 10.5.4, two groups have been created. Group 1 allows connections from any initiator on any network. Group 2 allows connections from any initiator on the 10.10.1.0/24 network. Click an initiator’s entry to display its Edit and Delete buttons.

Note

Attempting to delete an initiator causes a warning that indicates if any targets or target/extent mappings depend upon the initiator. Confirming the delete causes these to be deleted as well.

_images/initiator2a.png

Fig. 10.5.4 Sample iSCSI Initiator Configuration

10.5.4. Authorized Accesses

If you will be using CHAP or mutual CHAP to provide authentication, you must create an authorized access in Sharing Block (iSCSI) Authorized Accesses Add Authorized Access. This screen is shown in Figure 10.5.5.

Note

This screen sets login authentication. This is different from discovery authentication which is set in Target Global Configuration.

_images/authorized1.png

Fig. 10.5.5 Adding an iSCSI Authorized Access

Table 10.5.4 summarizes the settings that can be configured when adding an authorized access:

Table 10.5.4 Authorized Access Configuration Settings
Setting Value Description
Group ID integer allows different groups to be configured with different authentication profiles; for instance, all users with a Group ID of 1 will inherit the authentication profile associated with Group 1
User string name of user account to create for CHAP authentication with the user on the remote system; many initiators default to using the initiator name as the user
Secret string password to be associated with User; the iSCSI standard requires that this be between 12 and 16 characters
Peer User string only input when configuring mutual CHAP; in most cases it will need to be the same value as User
Peer Secret string the mutual secret password which must be different than the Secret; required if Peer User is set

Note

CHAP does not work with GlobalSAN initiators on Mac OS X.

As authorized accesses are added, they will be listed under View Authorized Accesses. In the example shown in Figure 10.5.6, three users (test1, test2, and test3) and two groups (1 and 2) have been created, with group 1 consisting of one CHAP user and group 2 consisting of one mutual CHAP user and one CHAP user. Click an authorized access entry to display its Edit and Delete buttons.

_images/authorized2a.png

Fig. 10.5.6 Viewing Authorized Accesses

10.5.5. Targets

Next, create a Target using Sharing Block (iSCSI) Targets Add Target, as shown in Figure 10.5.7. A target combines a portal ID, allowed initiator ID, and an authentication method. Table 10.5.5 summarizes the settings that can be configured when creating a Target.

Note

An iSCSI target creates a block device that may be accessible to multiple initiators. A clustered filesystem is required on the block device, such as VMFS used by VMware ESX/ESXi, in order for multiple initiators to mount the block device read/write. If a traditional filesystem such as EXT, XFS, FAT, NTFS, UFS, or ZFS is placed on the block device, care must be taken that only one initiator at a time has read/write access or the result will be filesystem corruption. If multiple clients need access to the same data on a non-clustered filesystem, use SMB or NFS instead of iSCSI, or create multiple iSCSI targets (one per client).

_images/target1a.png

Fig. 10.5.7 Adding an iSCSI Target

Table 10.5.5 Target Settings
Setting Value Description
Target Name string required value; base name will be appended automatically if it does not start with iqn
Target Alias string optional user-friendly name
Portal Group ID drop-down menu leave empty or select number of existing portal to use
Initiator Group ID drop-down menu select which existing initiator group has access to the target
Auth Method drop-down menu choices are None, Auto, CHAP, or Mutual CHAP
Authentication Group number drop-down menu None or integer representing number of existing authorized access

10.5.6. Extents

In iSCSI, the target virtualizes something and presents it as a device to the iSCSI client. That something can be a device extent or a file extent:

Device extent: virtualizes an unformatted physical disk, RAID controller, zvol, zvol snapshot, or an existing HAST device.

Virtualizing a single disk is slow as there is no caching, but virtualizing a hardware RAID controller has higher performance due to its cache. This type of virtualization does a pass-through to the disk or hardware RAID controller. None of the benefits of ZFS are provided and performance is limited to the capabilities of the disk or controller.

Virtualizing a zvol adds the benefits of ZFS, such as its read cache and write cache. Even if the client formats the device extent with a different filesystem, as far as FreeNAS® is concerned, the data benefits from ZFS features such as block checksums and snapshots.

When determining whether to use a file or a device extent, be aware that a zvol is required to take advantage of all VAAI primitives and is recommended when using virtualization software as the iSCSI initiator. The ATS, WRITE SAME, XCOPY and STUN, primitives are supported by both file and device extents. The UNMAP primitive is supported by zvols and raw SSDs. The threshold warnings primitive is fully supported by zvols and partially supported by file extents.

File extent: allows you to export a portion of a ZFS volume. The advantage of a file extent is that you can create multiple exports per volume.

Warning

For performance reasons and to avoid excessive fragmentation, it is recommended to keep the used space of the pool below 50% when using iSCSI. As required, you can increase the capacity of an existing extent using the instructions in Growing LUNs.

To add an extent, go to Sharing Block (iSCSI) Extents Add Extent. In the example shown in Figure 10.5.8, the device extent is using the export zvol that was previously created from the /mnt/volume1 volume.

Table 10.5.6 summarizes the settings that can be configured when creating an extent. Note that file extent creation will fail if you do not append the name of the file to be created to the volume/dataset name.

_images/extent2b.png

Fig. 10.5.8 Adding an iSCSI Extent

Table 10.5.6 Extent Configuration Settings
Setting Value Description
Extent Name string name of extent; if the Extent size is not 0, it cannot be an existing file within the volume/dataset
Extent Type drop-down menu select from File or Device
Serial string unique LUN ID; the default is generated from the system’s MAC address
Path to the extent browse button only appears if File is selected; browse to an existing file and use 0 as the Extent size, or browse to the volume or dataset, click Close, append the Extent Name to the path, and specify a value in Extent size; extents cannot be created inside the jail root directory
Device drop-down menu only appears if Device is selected; select the unformatted disk, controller, zvol, zvol snapshot, or HAST device
Extent size integer only appears if File is selected; if the size is specified as 0, the file must already exist and the actual file size will be used; otherwise, specify the size of the file to create
Logical Block Size drop-down menu only override the default if the initiator requires a different block size
Disable Physical Block Size Reporting checkbox if the initiator does not support physical block size values over 4K (MS SQL), check this box
Available Space Threshold string only appears if File or a zvol is selected; when the specified percentage of free space is reached, the system issues an alert; see VAAI Threshold Warning
Comment string optional
Enable TPC checkbox if checked, an initiator can bypass normal access control and access any scannable target; this allows xcopy operations otherwise blocked by access control
Xen initiator compat mode checkbox check this box when using Xen as the iSCSI initiator
LUN RPM drop-down menu do NOT change this setting when using Windows as the initiator; only needs to be changed in large environments where the number of systems using a specific RPM is needed for accurate reporting statistics
Read-only checkbox check this box to prevent the initiator from initializing this LUN

10.5.7. Target/Extents

The last step is associating an extent to a target within Sharing Block (iSCSI) Associated Targets Add Target/Extent. This screen is shown in Figure 10.5.9. Use the drop-down menus to select the existing target and extent. Click OK to add an entry for the LUN.

_images/target2b.png

Fig. 10.5.9 Associating a Target With an Extent

Table 10.5.7 summarizes the settings that can be configured when associating targets and extents.

Table 10.5.7 Target/Extents Configuration Settings
Setting Value Description
Target drop-down menu select the pre-created target
LUN ID drop-down menu select the value of the ID or type in the desired value
Extent drop-down menu select the pre-created extent

It is recommended to always associate extents to targets in a one-to-one manner, even though the GUI will allow multiple extents to be associated with the same target.

Note

Each LUN entry has Edit and Delete buttons for modifying the settings or deleting the LUN entirely. A verification popup appears when the Delete button is clicked. If an initiator has an active connection to the LUN, it is indicated in red text. It is recommended to clear initiator connections to a LUN before deleting it.

After iSCSI has been configured, remember to start it in Services Control Services. Click the red OFF button next to iSCSI. After a second or so, it will change to a blue ON, indicating that the service has started.

10.5.8. Connecting to iSCSI

To access the iSCSI target, clients must use iSCSI initiator software.

An iSCSI Initiator client is pre-installed with Windows 7. A detailed how-to for this client can be found here. A client for Windows 2000, XP, and 2003 can be found here. This how-to shows how to create an iSCSI target for a Windows 7 system.

Mac OS X does not include an initiator. globalSAN is a commercial, easy-to-use Mac initiator.

BSD systems provide command line initiators: iscontrol(8) comes with FreeBSD versions 9.x and lower, iscsictl(8) comes with FreeBSD versions 10.0 and higher, iscsi-initiator(8) comes with NetBSD, and iscsid(8) comes with OpenBSD.

Some Linux distros provide the command line utility iscsiadm from Open-iSCSI. Use a web search to see if a package exists for your distribution should the command not exist on your Linux system.

If a LUN is added while iscsiadm is already connected, it will not see the new LUN until rescanned with iscsiadm -m node -R. Alternately, use iscsiadm -m discovery -t st -p portal_IP to find the new LUN and iscsiadm -m node -T LUN_Name -l to log into the LUN.

Instructions for connecting from a VMware ESXi Server can be found at How to configure FreeNAS 8 for iSCSI and connect to ESX(i). Note that the requirements for booting vSphere 4.x off iSCSI differ between ESX and ESXi. ESX requires a hardware iSCSI adapter while ESXi requires specific iSCSI boot firmware support. The magic is on the booting host side, meaning that there is no difference to the FreeNAS® configuration. See the iSCSI SAN Configuration Guide for details.

The VMware firewall only allows iSCSI connections on port 3260 by default. If a different port has been selected, outgoing connections to that port must be manually added to the firewall before those connections will work.

If the target can be seen but does not connect, check the Discovery Auth settings in Target Global Configuration.

If the LUN is not discovered by ESXi, make sure that promiscuous mode is set to Accept in the vSwitch.

10.5.9. Growing LUNs

The method used to grow the size of an existing iSCSI LUN depends on whether the LUN is backed by a file extent or a zvol. Both methods are described in this section.

Enlarging a LUN with one of the methods below gives it more unallocated space, but does not automatically resize filesystems or other data on the LUN. This is the same as binary-copying a smaller disk onto a larger one. More space is available on the new disk, but the partitions and filesystems on it must be expanded to use this new space. Resizing virtual disk images is usually done from virtual machine management software. Application software to resize filesystems is dependent on the type of filesystem and client, but is often run from within the virtual machine. For instance, consider a Windows VM with the last partition on the disk holding an NTFS filesystem. The LUN is expanded and the partition table edited to add the new space to the last partition. The Windows disk manager must still be used to resize the NTFS filesystem on that last partition to use the new space.

10.5.9.1. Zvol Based LUN

To grow a zvol based LUN, go to Storage Volumes View Volumes, highlight the zvol to be grown, and click Edit zvol. In the example shown in Figure 10.5.10, the current size of the zvol named zvol1 is 4GB.

_images/grow1.png

Fig. 10.5.10 Editing an Existing Zvol

Enter the new size for the zvol in the Size field and click Edit ZFS Volume. This menu closes and the new size for the zvol is immediately shown in the Used column of the View Volumes screen.

Note

The GUI does not allow reducing (shrinking) the size of the zvol, as doing so could result in loss of data. It also does not allow increasing the size of the zvol past 80% of the volume size.

10.5.9.2. File Extent Based LUN

To grow a file extent based LUN, go to Services iSCSI File Extents View File Extents to determine the path of the file extent to grow. Open Shell to grow the extent. This example grows /mnt/volume1/data by 2 G:

truncate -s +2g /mnt/volume1/data

Go back to Services iSCSI File Extents View File Extents and click the Edit button for the file extent. Set the size to 0 as this causes the iSCSI target to use the new size of the file.